JPH0357606A - Tire forming mold - Google Patents

Abstract

PURPOSE:To prevent the clogging in venting means from developing and contrive to improve the exhausting function of the mold concerned by a constitution wherein the venting means to exhaust gas developed at tire forming outside consists of venting sheet, through holes in a profile ring and through holes in a mold holder. CONSTITUTION:In a tire forming mold main body, the exhaust course of gas developed at tire forming consists of a venting sheet 18, venting grooves 17 in a net ring, venting gaps 19, venting grooves 20 of each venting member, the through hole 21 of each bolt, venting grooves 22 of a profile ring and vent holes 5. The gas developed at tire forming flows through the ventig sheet 18 in the venting grooves 17 in the net ring and the venting gaps 19 and runs along the course indicated with the arrows (b) or the venting grooves 20 of the venting member, the through hole 21 of the bolt and the venting grooves 22 of the profile ring through the vent holes 5 so as to be exhausted outside.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a mold for molding a tire, particularly a profile ring having an inner peripheral surface corresponding to the tread surface of a tire to be molded, and a mold for molding a tire. A net ring consisting of lips and/or lugs for shaping, and a mold holder on which the profile ring is placed, and the profile ring is placed in the mold holder! ! A mold for tire shaping, which is configured so that the net ring is placed on the profile ring, and is provided with a ventilation means for exhausting gas generated during tire shaping to the outside. In this method, a ventilation sheet having flexibility, heat resistance, and air permeability, which constitutes a part of the ventilation means, is interposed between the net ring and the profile ring.・This invention relates to a mold for displaying a tire, which allows for easy fine adjustment of the fixing state of the net ring to the ring, and is equipped with a discharge means for forcibly discharging the gas to the outside through the ventilation means. .

[Prior Art] Generally, as shown in FIG. 3, a mold for shaping a tire has a design on the inner surface of the mold corresponding to the outer shape of the tire to be molded, that is, a tread portion corresponding to the tread surface of the tire. 31 and a rib portion 32 corresponding to the concave portion of the tire.The design and dimensional accuracy formed by the tread portion 31 and rib portion 32 improve the steering stability and running performance of the tire. Grounding property, 1! It is well known that properties such as sound prevention are affected. Conventionally, the above-mentioned tire molding molds have been made using the plaster molding method,
Sand casting method, ceramic 7-k casting method. Mold casting method. Other precision casting methods. Manufactured by integrally molding the tread portion 31 and the bone portion 32 by a manufacturing method such as an engraving method or electric discharge machining method, or by welding the bone portion 32 to the inner peripheral surface that constitutes the tread surface portion 3l in advance. It has been done. Therefore, every time the design was updated to improve the tire characteristics mentioned above, the entire mold had to be renewed. Furthermore, there were drawbacks such as not only the cost of mold manufacturing increasing due to the need for rework and finishing that took a huge amount of man-hours, but also the manufacturing period required. In addition, a gas vent passage (not shown) for discharging gas generated during tire molding is provided, for example, in the tread portion 31, so that rubber may enter the gas vent passage and cause undesired damage to the surface of the tire. This has disadvantages such as the formation of small protrusions or clogging of the gas vent passage, which impedes the exhaust function and causes defective tires. Therefore, in order to solve the above-mentioned drawbacks, a profile ring having an inner circumferential surface corresponding to at least the outer shape including the tread of the tire to be molded, and a joint surface that comes into contact with the inner circumferential surface of the profile ring are provided. and comprising a net ring consisting of ribs and/or lugs for molding the recess of the tire to be molded, and a mold holder on which the profile ring is placed;
The profile ring is placed on the mold holder, and the Nent ring is placed on the profile ring, and a ventilation means is formed on at least the joint surface of the Nesoto ring. A ventilation hole different from the ventilation means is provided in the mold holder to allow ventilation to the outside, thereby achieving high precision,
A tire molding mold (patent application filed in 1983) which is designed to reduce manufacturing costs and shorten the manufacturing period, as well as to prevent the formation of the aforementioned undesired small protrusions and clogging of gas vent passages. -95302) is known.

[Problem to be solved by the invention]

In the tire molding mold made up of the net ring, profile ring, and mold holder, when the net ring is placed on the profile ring, the joint surface of the net ring is It is placed in direct contact with the inner peripheral surface of the profile ring. Therefore, the joint surface of the above-mentioned net ring and the above-mentioned profile
High precision is required for surface machining with the inner peripheral surface of the ring.

That is, if the accuracy of the finishing surface is poor, play may occur between the net ring and the profile ring, or the net ring may be deformed. Therefore, the surface machining between the joint surface of the Nenoto ring and the inner circumferential surface of the profile ring must be carefully performed using highly skilled and highly skilled machining techniques, which increases the number of machining steps, machining time, and machining costs. There was an undesirable problem.

In addition, in the conventional tire molding mold described above, the bonding surface of the net ring is in direct contact with the inner peripheral surface of the profile ring, so the surface roughness of the bonding surface of the net ring must be roughened. This has been designed to facilitate degassing. In this way, roughening the surface roughness of the bonding surface of the net ring made it more difficult to improve the surface machining accuracy of the bonding surface of the net ring. [Means for Solving the Problems] The present invention aims to solve the above-mentioned problems. Therefore, the tire molding mold of the present invention has a tire molding die that corresponds to at least the outer shape of the tire to be molded, including the tread surface. A profile ring having an inner circumferential surface, and a rib and/or lug having a joint surface that abuts the inner circumferential surface of the profile ring and forming the concave portion of the tire to be imposing. ring, and a mold holder on which the Kamigotsuki brofainore ring is placed, the profile ring is placed on the mold holder, and the net ring is placed on the profile ring. In a tire molding mold, the tire molding mold is provided with a ventilation means for discharging gas generated during tire molding to the outside, and configured so that the inside and outside of the mold are communicated through the ventilation means, The ventilation means communicates with a ventilation sheet having flexibility, heat resistance, and air permeability interposed between the inner circumferential surface of the profile ring and the joint surface of the net ring, and the ventilation sheet having flexibility and heat resistance and air permeability. The mold holder is characterized by comprising a profile ring through hole that penetrates the profile ring, and a mold holder through hole that communicates with the profile ring through hole and penetrates the mold holder.
This will be explained below with reference to the drawings. [Example] Fig. 1 is an explanatory diagram for explaining the basic structure of the present invention, and Fig. 2 is an explanatory diagram of an embodiment of a tire mold body to which the present invention is applicable. Figure (A) is a developed plan view of the mold surface, and Figure 2 (B) is a sectional view taken along arrow A-A in Figure 2 (A). Figure 2 (C) is the arrow B- shown in Figure 2 (A).
Cross-sectional view at B. Figure 2 (D) is a perspective view of the Nent ring material. Figure 2 (E) is Figure 2 (D) illustrated arrow C-C
Figure 2 (F) shows a perspective view of the net ring. The reference numeral 1 in the figure is the upper mold holder. 2 is the lower mold holder. 3 is net ring, 3-1
is the joint surface of the net ring 3, 3'' is the wire material, 4 is the profile ring, and 4-■ is the ventilation member.4
-2 is a ventilation member fitting groove (hereinafter simply referred to as a fitting groove), 4
-3 is the inner peripheral surface of the profile ring (hereinafter simply referred to as the profile surface). 4-4 is the outer circumferential surface of the profile ring. 5 is a ventilation hole. 6 is a switching means, 7 is a discharge means, and 8 is a pressurizing means. 9 is a rib, 10 is a lug. 11 is the shoulder blue part (
Although this corresponds to a lug in the sense of the present invention, it is called the shoulder blue part to distinguish it from the above-mentioned lug 10). 12
and 13 is a blade 5, 14 is a connecting member, 15 and 16 are vaults, 17 is a net ring ventilation groove, and 18 is a ventilation sheet, which has good air permeability, flexibility, and heat resistance, such as carbon fiber. thing, 1
9 is the ventilation gap. 20 is a ventilation groove for the ventilation member. 21 represents the vault through hole, and 22 represents the profile ring ventilation groove. FIG. 1 is an explanatory diagram for explaining the basic configuration of the present invention. Prior to the explanation of FIG. 1, an embodiment of a tire mold body to which the present invention is applicable is shown in FIG. This will be explained in relation to (A) to Fig. 2 (F). Although Fig. 2 shows the structure of the lower mold, the upper mold has basically the same structure. The illustrated example in FIG. 2 is a lower mold of a tire molding mold constituted by a net ring 3, a profile ring 4, and a lower mold holder 2. The profile ring 4 is fixed to the profile ring 4 via the ventilation sheet 18 using a tapered pin or a straight pin (which may be a taper pin or a straight pin), and then the profile ring 4 is further fixed to the lower mold holder 2 using the vault 16. . And the above profile ring 4
The profile surface 4-3 corresponds to the tread surface of the tire to be formed, and the lip 9, lug 10 . Shiruda bone part 11. Blades 12 and 13 correspond to the recesses of the tire to be formed. The net ring 3 is produced by, for example, performing electrical discharge machining on the net ring material 3 as shown in FIG. 2(D), as shown by the dotted line in FIG. 2(E). Rib 9. The lugs 10, the shoulder bones 11, and the connecting members 14 are shaped like a net, and a perspective view of the net ring 3 made in this way is shown in FIG.
) is shown. In addition, on the joint surface 3-1 of the Nesoto ring 3, a Nesoto ring ventilation groove 17 (shown in FIG. 2(E)) is formed along the ribs 9, lugs 10, etc. In addition, the Tokyoufunoto Ring 3 is shown in Figure 2 (C).
As shown in the figure, the above-mentioned profile ring is passed through a ventilation sheet 18 (about 0.01 to 0.1 rm thick) made of, for example, carbon fiber, which has good ventilation, flexibility, and heat resistance. It is fixed at 4. The ventilation sheet 18 has good air permeability, so that generated gas can pass through it sufficiently, and has heat resistance, which prevents deterioration due to high temperature generated gas, and also has flexibility, so it is suitable for the profile ring 4. Fine adjustment of the fixation condition of the Nesoto ring 3 described above becomes easy.
The connecting member l4 is removed after the neck ring 3 is fixed to the profile ring 4. A fitting groove 4-2 is narrowed in advance in the profile surface 4-3 of the profile ring 4, and a ventilation member 4-1 is embedded in the fitting groove 4-2. Note that there is a second groove between the fitting groove 4-2 and the ventilation member 4-1.
Diagram (C) Indicated arrow dimension a (0.005 to 0.05
It is left open so that there is a ventilation gap 19 of about mm). A ventilation groove 20 is formed on the bottom surface of the ventilation member 4-1.

Further, on the profile ring outer circumferential surface 4-4, as shown in FIG. Ventilation grooves 22 are featured. Furthermore, the lower mold holder 2 has a ventilation hole 5 (shown in FIG. 2(B)) that communicates with the profile ring ventilation groove 22.
is taking shape.

As explained above, in the tire mold body shown in FIG.
, ventilation gap 19, ventilation member ventilation groove 20, vault hole 21. Profile ring ventilation groove 22. and a ventilation hole 5 (hereinafter, each element constituting the above-mentioned exhaust path will be collectively referred to as an exhaust mechanism). That is, the gas generated during tire molding flows into the net/ring ventilation groove 17 and the ventilation gap [19] through the ventilation sheet 18, and flows into the ventilation member ventilation groove 2 along the arrow b in FIG. 2(C).
0, it is discharged to the outside through the vault through hole 21, the profile ring ventilation groove 22, and further through the ventilation hole 5. In addition,
Since the gas generated when the tire is inflated is introduced into the ventilation gap 19 through the ventilation sheet, the net/ring ventilation groove 17 may be omitted. In addition, a ventilation member 4- provided to constitute a part of the above-mentioned exhaust mechanism.
1 may be omitted. Although the exhaust mechanism in the lower mold has been described above, the exhaust mechanism in the upper mold is also the same. As shown in FIG. 1, the present invention includes an exhaust means 7 for sucking gas generated during tire molding through the exhaust mechanism and exhausting it to the outside, and a high temperature (up to 150 degrees Celsius) inside the exhaust mechanism. a pressurizing means 8 for pumping air at a temperature of about 180 degrees to about 180 degrees;
A switching means (for example, 7a.T61 switching hub) 6 is provided for switching between the ejection means 7 and the pressurizing means 8,
The switching means 6 is connected to the respective ventilation holes 5 provided in the upper mold holder 1 and the lower mold holder 2 through a pipe 5''.

Hereinafter, the switching means 6, the discharge means 7. and pressurizing means 8
The manner of gas discharge and the manner of pressurizing high-temperature air with respect to the above exhaust mechanism will be explained.

During tire molding (vulcanization), the switching means 6 is operated to connect the ventilation hole 5 and the discharge means 7. As a result, the gas generated when the tire is inflated is rapidly discharged to the outside via the exhaust mechanism described above, making it possible to improve the exhaust function for the generated gas and to prevent gas from being generated to the outside. Because the time until discharge is shortened,
The drop in gas temperature is also relatively small, and the generated gas remains in a gaseous state until it is exhausted to the outside, making it possible to prevent the exhaust mechanism from becoming clogged. Note that the discharge means 7 is not limited to one that performs forced discharge, but may also be one that causes natural discharge. From the end of one tire molding to the start of the next tire molding, the switching means 6 is operated so that the ventilation hole 5 and the pressurizing means 8 are connected. As a result, high-temperature air is forced into the exhaust mechanism, and even during non-vulcanization, it is possible to at least prevent the temperature of the exhaust mechanism from decreasing, so that the generated gas can be discharged. It is possible to further reduce the temperature drop. In addition, by force-feeding high-temperature air to the exhaust mechanism, it is possible to blow away dust and unsolidified liquid materials adhering to the exhaust mechanism. The reason why the temperature of the compressed air to the exhaust mechanism is set to about 150 to 180 degrees Celsius is to make it about the same as the generation temperature of the generated gas.

As explained above, throughout the tire shaping work, high-temperature gas is constantly flowing through the exhaust mechanism during vulcanization and non-vulcanization, so at least the internal temperature of the exhaust mechanism can be maintained at the desired temperature. It is possible to maintain within the temperature range,
It is possible to prevent clogging of the exhaust mechanism mentioned above due to the exhaust of gas generated during tire vulcanization. Further, as shown in FIG. 2(C), the net ring 3 is made of a flexible ventilation sheet 18 (thickness: 0.01 to 0.1 txm) made of, for example, carbon fiber.
Since it is configured to be fixed to the profile ring 4 via the angle τ}, it is easy to finely adjust the fixing state of the Nenoto ring 3 to the profile ring 4. Also, net ring 3 for gas release.
Surface roughness smoothing processing of the joint surface 3-1 becomes unnecessary.

Although a so-called full-mold type tire molding mold (example shown in FIG. 2) has been cited as a tire molding mold to which the present invention is applied, the scope of the present invention is not limited to this. The present invention can also be applied to tire molding molds of other methods such as the so-called sector mold method.

〔Effect of the invention〕

As explained above, according to the present invention, in a tire molding mold equipped with a ventilation means for exhausting gas generated during tire molding to the outside, the gas is forcibly discharged to the outside through the ventilation means. and a pressurizing means for pumping high-temperature gas to the ventilation means, and selectively driving the ejecting means and pressurizing means as necessary,
In addition to preventing clogging in the ventilation means,
It is possible to provide a tire shape mold that makes it possible to improve the exhaust function. Further, an elastic ventilation sheet, which constitutes a part of the ventilation means, is interposed between the net ring and the profile ring. Therefore, it is easy to finely adjust the fixing state of the net ring to the profile ring, and the net ring for degassing can be easily adjusted.
There is no need to process the surface roughness of the joint surface of the ring.

[Brief explanation of drawings]

FIG. 1 is an explanatory diagram for explaining the basic structure of the present invention, and FIG. 2 is an explanatory diagram of an embodiment of a tire mold body to which the present invention is applied. is a developed plan view of the mold surface, FIG. 2(B) is a sectional view taken along arrow A-A in FIG. 2(A), and FIG. 2(C) is a cross-sectional view taken along arrow A-A in FIG. 2(A)
A sectional view at B, FIG. 2(D) is a perspective view of the Nenoto ring material, and FIG. 2(E) is an arrow shown in FIG. 2(D).
2(F) is a perspective view of the Nenoto ring, and FIG. 3 is an explanatory diagram of a general example of a tire molding die. In the figure, 1 is the upper mold holder. 2 is the lower mold holder, 3 is the net ring, and 3-1 is the joint surface of the net ring 3.
3" is the net ring material, 4 is the profile ring. 4-1 is the ventilation member, 4-2 is the fitting groove, 4-3 is the profile surface, 4-4 is the profile ring outer surface. 5 is the ventilation hole. , 6 is a switching means, 7 is a discharge means, 8 is a pressurizing means,
9 is a rib, 10 is a lug, 11 is a sill rib, 12 and 13 are blades, 14 is a connecting member, 15 and 16 are vaults, 17 is a Nenoto ring ventilation groove, and 18 is a ventilation sheet. 19 represents a ventilation gap, 20 represents a ventilation member ventilation groove, 21 represents a vault through hole, and 22 represents a profile ring ventilation groove.

Claims (2)

[Claims] (1) A profile ring having an inner peripheral surface corresponding to at least the outer shape including the tread of the tire to be molded, and a concave portion of the tire to be molded, having a joint surface that comes into contact with the inner peripheral surface of the profile ring. a net ring consisting of ribs and/or lugs for molding the profile ring, and a mold holder on which the profile ring is placed; The net ring is placed on a ring, and a ventilation means is provided to exhaust gas generated during tire molding to the outside.
In a tire molding mold configured such that the inside and outside of the mold communicate with each other through the ventilation means, the ventilation means includes a profile ring that communicates with the ventilation sheet and penetrates the profile ring. A tire molding mold comprising: a through hole; and a mold holder through hole communicating with the profile ring through hole and penetrating the mold holder. (2) In the above claim (1), a discharge means for forcibly discharging gas to the outside of the mold via the vent means; a pressurizing means for pumping the high temperature gas through the vent means; It is characterized by comprising a switching means for switching between the evacuation means and the pressurizing means, and configured such that the evacuation means and the pressurizing means are connected to the ventilation means via the switching means so as to be freely ventilable. Mold for tire molding.