DE102012108803A1 - Device for vulcanization of vehicle tire, has shell and/or ring thermally decoupled from upper mold plate of vulcanization container and center mechanism by circular heat insulation at shell such that temperature difference is adjusted - Google Patents

Abstract

The device has a heating mold (1) including a side wall shell (3) and/or a bead ring (2), which includes heating sources (5, 6) independent of an external heater. The heating sources are spatially provided in direct proximity to a tire region to be vulcanized. The shell and/or the ring are thermally decoupled from an upper mold plate (13) of a vulcanization container and a center mechanism (12) by a circular heat insulation (8) at the shell such that a significant temperature difference between a temperature of the shell and/or the ring and a temperature of profile segments (4) is adjusted.

Description

The invention relates to a device for vulcanization of a vehicle tire.

The tire vulcanization is carried out in heating presses, in which the green tire is inserted into suitable mold segments and vulcanized under the action of heat and pressure. On the inside of the tire, a flexible bellows is applied to the tire, which is acted upon by a heating medium and in this way supplies the required vulcanization energy to the green tire from the inside. The supply of Vulkanisationsenergie on the inside of the tire is referred to as internal heating. The required vulcanization temperatures and cure time are dependent on various parameters, e.g. of the tire type. From the outside, the green tire is heated by means of heating plates and conical ring adjacent to the mold.

Under certain conditions, there is the problem of undesirably high temperatures in certain parts of the tire, e.g. in the area of the bead and the side wall. Certain parts of the tire, in particular the bead or the side wall, can be strongly crosslinked at too high temperatures and long vulcanization times, whereby the product quality and tire properties can be impaired.

The invention has for its object to provide a device for the vulcanization of a vehicle tire, in which the vehicle tire is produced with a high product quality and improved tire properties. Another object is to shorten the overall cure time, thereby increasing the number of cured tires per cure press.

The object is achieved according to claim 1 by a device according to the preamble and the characterizing features of claim 1, characterized in that the side wall shell and / or the bead ring of the heating mold have a respective independent of the cone ring heat source, wherein the heat source of the bead ring and / or the sidewall shell is in close proximity to the tire area to be vulcanized, the sidewall shell and / or bead ring being thermally decoupled by thermal insulation from surrounding components of the vulcanization container and the center mechanism of the device, thereby providing a significant temperature difference between the sidewall shell temperature and / or the bead ring and the temperature at the profile segments is adjustable.

The thermal insulation in conjunction with the self-sufficient heat sources, a thermal decoupling of the bead ring and the side wall shell is achieved by the tread area. This allows a targeted temperature control of the individual tire areas The tread area and the tire shoulders can be vulcanized, for example, with higher temperatures, whereby the vulcanization time per tire can be significantly reduced. Another advantage is the improvement of tire properties, since the different tire areas are each vulcanized with an optimum vulcanization temperature. These improved tire properties include, in particular, reduced rolling resistance, a reduction of the braking distance on wet roads and further driving characteristics improvements. In addition, a reduction in energy costs can be achieved because there are shorter paths between the heat sources in the sidewall / bead area and the green tire to be vulcanized.

In an advantageous development of the invention, it is provided that the side wall shell and the bead ring of the heating mold have an independent of the cone heating heat source, with the heat sources different temperatures (heating + cooling) in the side wall shell and the bead ring are adjustable. In this way, both the relatively thin side wall and the slightly thicker tire bead can be tempered with different vulcanization temperatures.

In a further advantageous embodiment of the invention it is provided that a heat insulation between the side wall shell and the bead ring is arranged. The thermal insulation achieves effective thermal decoupling between the two parts of the heating mold.

In a further advantageous embodiment of the invention it is provided that a heat insulation between the profile segments and the side wall shells is arranged.

In a further advantageous embodiment of the invention it is provided that the heat insulation is formed in the form of grooves on the surfaces of the side wall shell or the bead ring, which prevents heat transfer from the surrounding components. A corresponding thermal insulation can be realized in a simple manner. The air grooves ensure a good and effective heat insulation.

In a further advantageous embodiment of the invention, it is provided that the heat insulation is designed in the form of insulating material, which prevents heat transfer from the surrounding components. By an appropriate insulating material, the formation of thermal bridges can be excluded in a simple manner.

In a further advantageous embodiment of the invention, it is provided that the thermal insulation consists of a pressure-stable and temperature-resistant plastic material. In this way, the thermal insulation withstands the high temperature stress associated with vulcanization.

In a further advantageous embodiment of the invention it is provided that the thermal insulation, e.g. made of Teflon material. Teflon material is a suitable material that meets the requirements.

In a further advantageous development of the invention, it is provided that the upper and / or the lower heating plate of the vulcanization container has a thermal decoupling joint, whereby the steam chambers in the heating plate supply thermal energy essentially exclusively to the profile segments. The decoupling joint thermally decouples the part of the heating plate which lies in the region of the side wall shell and the bead ring from the rest of the heating plate.

In a further advantageous embodiment of the invention, it is provided that temperature sensors for temperature control of the heating mold are arranged in the profile segments, side wall shells and / or bead rings. As a result, it is possible in a simple manner to realize a controlled temperature profile in the profile segments and in the sidewall / bead region, following a specific temperature target curve.

In a further advantageous development of the invention, it is provided that any temperature differences can be set between the temperatures of the profile segments, side wall shells and bead rings. By appropriate temperature differences optimal vulcanization temperatures can be set in the different areas of the heating mold.

Reference to an embodiment of the invention will be explained in more detail. It shows:

1 a device according to the invention for the vulcanization of a vehicle tire.

The 1 shows the heating mold according to the invention 1 , In the heating form 1 In vulcanization, an unillustrated green tire is arranged. All components of the heating mold 1 and the surrounding Vulkanisationscontainerers are substantially rotationally symmetrical to the axis of symmetry 22 , this figure shows a sectional view. The external heating essentially comprises the heat source 19 in the upper heating plate 14 , the heat source 21 in the lower heating plate 18 and the heat source 20 in the cone ring 17 , The illustrated arrows show the heat flow in the direction of the heating mold, in particular in the direction of the profile segment 4 ,

About the heat sources, the green tire on its outside on the Heizform 1 Heat supplied. The internal heating is formed by a bellows interior, not shown, and by a bellows, not shown, wherein the bellows interior is acted upon by a corresponding heating medium.

The heating mold essentially comprises the upper and lower bead ring 2 , the upper and lower side wall shell 3 and the profile segments 4 , The heating form 1 lies on its inside directly to the green tire and leads him to vulcanization energy in the form of heat. The bead ring 2 and the side wall shells 3 each have independent heat sources 5 and 6 on. The heat sources 5 and 6 lie in close proximity to the tire bead and the sidewall of the green tire. Both heat sources 5 and 6 can be applied to different temperatures. The heat source 5 and 6 For example, they are designed as steam chambers, which are heated with a heating medium in the form of steam. The bead rings 2 , the side wall shells 3 and the profile segments 4 are each thermally decoupled via appropriate thermal insulation. The arrangement of the thermal insulation is shown in the form of a dashed line, which thermally separate the components with each other. There is also a thermal insulation 9 between the bead ring 2 and the center mechanism 12 the device arranged to prevent heat transfer from the internal heating. The thermal insulation 10 is between the bead ring and the sidewall shell 3 arranged and prevents heat transfer between these two components. The thermal insulation 11 is disposed between the sidewall shell and the profile segments. The vulcanization container essentially comprises the surrounding components surrounding the heating mold 1 are arranged. Between the cone ring 17 and the profile segments 4 is the segment shoe 16 of Vulkanisationscontainerers arranged. The decoupling joint 15 in the upper and lower heating plate 14 and 18 ensures that the heat transfer in the remaining part of the heating plate is largely prevented. This way, with the heat sources 19 and 21 essentially the profile segments 4 Heat energy supplied.

LIST OF REFERENCE NUMBERS

1

heating form

2

bead

3

Sidewall shell

4

profile segment

5

Heat source in the bead ring

6

Heat source in sidewall shell

7

circumferential heat insulation on the bead ring

8th

circumferential heat insulation on the side wall shell

9

Thermal insulation between bead ring and center mechanism

10

 Heat insulation between bead ring and side wall shell

11

 Thermal insulation between side wall shell and profile segments

12

 center mechanism

13

 Upper mold plate of the vulcanization container

14

 upper heating plate of the vulcanization container

15

 Decoupling joint in the heating plate

16

 Segment shoe of the vulcanization container

17

 Cone ring of the vulcanization container

18

 lower heating plate of the vulcanization container

19

 Heat source in upper heating plate of vulcanization container (e.g., steam chamber for external heating)

20

 Heat source in cone ring (e.g., steam chamber)

21

 Heat source in lower heating plate (e.g., steam chamber)

22

 Rotational symmetry axis

Claims (11)

Device for vulcanization of a vehicle tire with a heating mold ( 1 ) and a Vulkanisationscontainer, wherein the Heizform ( 1 ) Profile segments ( 4 ), Side wall shells ( 3 ) and bead rings ( 2 ) for heating the outside of the vehicle tire, wherein in the Vulkanisationscontainer an external heating ( 19 . 20 . 21 ) and the profile segments ( 4 ), Side wall shells ( 3 ) and bead rings ( 2 ) of components ( 13 . 14 . 16 . 17 . 18 ) of the Vulkanisationscontainers be included, whereby the external heating ( 19 . 20 . 21 ) at least the profile segments ( 4 ) Is supplied in the form of heat, wherein the external heating several heat sources ( 19 . 20 . 21 ) in components of the Vulkanisationscontainers, is supplied via an internal heating the vehicle tire from the inside of vulcanization energy in the form of heat, characterized in that the side wall shell ( 3 ) and / or the bead ring ( 2 ) of the heating mold ( 1 ) a heat source independent of the external heating ( 5 . 6 ), wherein the heat sources ( 5 . 6 ) are in close proximity to the area of the tire to be vulcanized, the sidewall shell ( 3 ) and / or the bead ring ( 2 ) by a thermal insulation ( 8th ) of surrounding components ( 13 ) of the vulcanization container and the center mechanism ( 12 ) of the device are thermally decoupled, whereby a significant temperature difference between the temperature of the side wall shell ( 3 ) and / or the bead ring ( 2 ) as well as the temperature at the profile segments ( 4 ) is adjustable. Apparatus according to claim 1, characterized in that the side wall shell ( 3 ) and the bead ring ( 2 ) of the heating mold ( 1 ) a heat source independent of the external heating ( 5 . 6 ), wherein with the heat sources ( 5 . 6 ) different temperatures in the sidewall shell ( 3 ) and / or the bead ring ( 2 ) are adjustable. Device according to one of the preceding claims, characterized in that a thermal insulation ( 10 ) between the sidewall shell ( 3 ) and the bead ring ( 2 ) is arranged. Device according to one of the preceding claims, characterized in that a thermal insulation ( 11 ) between the profile segments ( 4 ) and the side wall shells ( 3 ) is arranged. Device according to one of the preceding claims, characterized in that the thermal insulation ( 8th . 9 . 10 . 11 ) in the form of grooves on the surfaces of the sidewall shell ( 3 ) or the bead ring ( 2 ) is formed, which prevents heat transfer from the surrounding components. Device according to one of the preceding claims, characterized in that the heat insulation is in the form of insulating material which prevents heat transfer from the surrounding components. Device according to one of the preceding claims, characterized in that the thermal insulation ( 8th . 9 . 10 . 11 ) consists of a pressure-stable and temperature-resistant plastic material. Device according to one of the preceding claims, characterized in that the thermal insulation ( 8th . 9 . 10 . 11 ) consists of Teflon material. Device according to one of the preceding claims, characterized in that the upper and / or the lower heating plate 14 . 18 of the vulcanization container a decoupling joint ( 15 ), whereby the steam chambers ( 19 . 21 ) in the heating plate substantially exclusively the profile segments ( 4 ) Supplies heat energy. Device according to one of the preceding claims, characterized in that in the profile segments ( 49 , Sidewall shells ( 3 ) and / or bead rings ( 2 ) Temperature sensors for temperature control of the heating mold ( 1 ) are arranged. Device according to one of the preceding claims, characterized in that between the temperatures of the profile segments ( 4 ), Side wall shells ( 3 ) and bead rings ( 2 ) Any temperature differences are adjustable.

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