U.S. patent application number 13/409468 was filed with the patent office on 2012-06-28 for device for producing a tread for a vehicle tire.
This patent application is currently assigned to CONTINENTAL AKTIENGESELLSCHAFT. Invention is credited to UDO FRERICHS.
Application Number | 20120160423 13/409468 |
Document ID | / |
Family ID | 38093460 |
Filed Date | 2012-06-28 |
United States Patent
Application |
20120160423 |
Kind Code |
A1 |
FRERICHS; UDO |
June 28, 2012 |
DEVICE FOR PRODUCING A TREAD FOR A VEHICLE TIRE
Abstract
A tread for a vehicle tire has an electrically conducting layer
axially inside a portion of a first, radially outer rubber layer of
the tread. The electrically conductive layer extends from a second,
radially inner rubber layer of the tread on the radially inner side
of the tread rubber material up to a ground contact surface of the
tread. During the tire build-up, an accumulation of rubber material
of higher electrical conductivity is built on a first rubber layer
of higher electrical conductivity. The accumulation is formed into
a ridge web and then less-conductive rubber is laid laterally next
to the web, such that the web of rubber material reaches up to the
ground contact surface in the finished vehicle tire. The web is
shaped by forming rollers, by baffles, or by a forming ring with a
corresponding shape.
Inventors: |
FRERICHS; UDO; (LANGENHAGEN,
DE) |
Assignee: |
CONTINENTAL
AKTIENGESELLSCHAFT
HANNOVER
DE
|
Family ID: |
38093460 |
Appl. No.: |
13/409468 |
Filed: |
March 1, 2012 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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12245863 |
Oct 6, 2008 |
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13409468 |
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PCT/EP2007/001429 |
Feb 20, 2007 |
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12245863 |
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Current U.S.
Class: |
156/416 ;
156/414 |
Current CPC
Class: |
B60C 11/005 20130101;
B29D 30/60 20130101; B60C 19/08 20130101; B29D 2030/526
20130101 |
Class at
Publication: |
156/416 ;
156/414 |
International
Class: |
B29D 30/24 20060101
B29D030/24 |
Foreign Application Data
Date |
Code |
Application Number |
Apr 5, 2006 |
DE |
102006015910.1 |
Claims
1. A device for producing a tread of a vehicle tire, the tread
having a radially outer rubber layer, a radially inner rubber
layer, and an electrically conductive layer disposed axially inside
a portion of the radially outer rubber layer and extending from the
radially inner rubber layer up to a ground contact surface of the
tread, the device comprising: a building body rotatably mounted
about an axis of rotation for building up rubber layers; a drive
connection for rotating said building body about the axis of
rotation; means for positioning and laying rubber material on the
building body; means for shaping built-up accumulations of rubber
material on said building body and configured to form therefrom a
web of rubber material extending from the radially inner rubber
layer to the ground contact surface of the tread; and means for
laying the radially outer rubber layer laterally adjacent the web
of rubber material.
2. The device according to claim 1, wherein said shaping means are
configured for shaping the accumulation of rubber material of
higher electrical conductivity into a web with a cross-sectional
contour tapering outwardly in a radial sense in its cross-sectional
planes containing the axis of the vehicle tire.
3. The device according to claim 1, wherein said drive connection
is configured to rotate said building body about an axis of
rotation while said positioning and laying means build up the
material on a building surface of said building body.
4. The device according to claim 3, wherein said building body is a
building drum.
5. The device according to claim 3, wherein said building body is a
toroidal building core.
6. The device according to claim 3, wherein said building surface
is part of a solid surface.
7. The device according to claim 3, wherein said building surface
is part of an elastic surface.
8. The device according to claim 3, wherein said building surface
is a surface of an inflated bladder.
9. The device according to claim 1, wherein said shaping means is a
contoured shaping body.
10. The device according to claim 9, wherein said shaping body is a
baffle configured to be moved laterally and vertically towards the
accumulation of material and to be held substantially stationary as
the accumulation of material is moved past said baffle.
11. The device according to claim 1, wherein said shaping means is
a forming roller configured to be moved laterally and vertically
towards the accumulation of material and to be biased against the
accumulation of material as the accumulation of material is moved
past said forming roller.
12. The device according to claim 1, wherein said shaping means is
a forming ring configured to be brought up to the accumulation of
material coaxially and radially outside the first rubber layer,
said forming ring including an annular stop for deforming the
accumulation of material over the entire circumference of the first
rubber layer.
Description
CROSS-REFERENCE TO RELATED APPLICATION
[0001] This application is a continuation of copending patent
application Ser. No. 12/245,863, filed Oct. 6, 2008, which was a
continuation of international patent application PCT/EP2007/001429,
filed Feb. 20, 2007, which designated the United States; this
application also claims the priority, under 35 U.S.C. .sctn.119, of
German patent application No. DE 10 2006 015 910.1, filed Apr. 5,
2006; the prior applications are herewith incorporated by reference
in their entirety.
BACKGROUND OF THE INVENTION
Field of the Invention
[0002] The invention relates to a method for producing a tread for
a vehicle tire--in particular a pneumatic vehicle tire--which is
provided with an electrically conducting layer, which is arranged
axially inside a portion of a first, radially outer rubber layer of
the tread that is formed from a first rubber material, wherein the
electrically conductive layer extends from a second, radially inner
rubber layer of the tread of a second rubber material on the
radially inner side of the tread rubber material up to a ground
contact surface of the tread and wherein both the rubber material
of the electrically conducting layer and the rubber material of the
second, radially inner rubber layer of the tread have a higher
electrical conductivity than the rubber material of the first,
radially outer rubber layer.
[0003] A method for producing a pneumatic vehicle tire of this type
is known, for example, from European patent EP 1 175 992 B1 (cf.
U.S. Patent Application Publication No. US 2002/0007893 A1). There,
an electrically conductive layer is formed axially inside a portion
of a first radially outer rubber layer formed from a cap mixture,
wherein the electrically conductive layer extends from the second
rubber layer, formed from a base mixture radially inside the outer
rubber layer, as a web of narrow cross section radially outward up
to the ground contact surface of the tread. The layer forming the
narrow web is produced by a narrow ribbon-shaped strip of rubber
being wound around the second rubber layer in a number of turns
arranged radially one on top of the another. The congruent turns of
the ribbon-shaped rubber strip are in each case formed with the
same axial width. Subsequently, the rubber material for forming the
first rubber layer is built up successively on both sides of the
web, wherein a dependable connection between the web and the rubber
material for forming the first rubber layer also has to be produced
without any formation of air pockets. Adequately high pressing
forces are required for this. In order that the web cannot
inadmissibly tilt out of its position in the process, the rubber
ribbon must be made as wide as possible. However, being made wide
has the effect of reducing the contact surface area of the first
rubber layer of the vehicle tire, formed from the cap mixture, with
respect to the surface of the roadway that is important for the
running characteristics.
SUMMARY OF THE INVENTION
[0004] It is accordingly an object of the invention to provide a
method for producing a tread for a vehicle tire which overcomes the
above-mentioned disadvantages of the heretofore-known devices and
methods of this general type and which makes possible simple,
dependable production of a tread possible for a vehicle tire--in
particular a pneumatic vehicle tire--which is provided with an
electrically conducting layer, which is arranged axially inside a
portion of a first, radially outer rubber layer of the tread that
is formed from a first rubber material, wherein the electrically
conductive layer extends from a second, radially inner rubber layer
of the tread of a second rubber material on the radially inner side
of the tread rubber material up to a ground contact surface of the
tread and wherein both the rubber material of the electrically
conducting layer and the rubber material of the second, radially
inner rubber layer of the tread have a higher electrical
conductivity than the rubber material of the first, radially outer
rubber layer, for which it is possible to design the running
properties in an optimized manner in spite of good electrical
dischargeability from the second rubber layer into the surface of
the roadway.
[0005] With the foregoing and other objects in view there is
provided, in accordance with the invention, a method of producing a
tread for a vehicle tire.
[0006] The tread having a radially outer rubber layer formed of a
first rubber material; a radially inner rubber layer formed of a
second rubber material; an electrically conductive layer disposed
axially inside a portion of the radially outer rubber layer, the
electrically conductive layer extending from the radially inner
rubber layer up to a ground contact surface of the tread; and a
rubber material of the electrically conductive layer and the second
rubber material of the radially inner rubber layer having a higher
electrical conductivity than the first rubber material of the
radially outer rubber layer.
[0007] The method according to the invention comprises the
following steps:
[0008] building up a first rubber layer of a relatively higher
electrical conductivity, formed to extend over a circumference of
the vehicle tire and having a radially outer surface, and building
up an accumulation of rubber material of a relatively higher
electrical conductivity, formed to extend over the circumference of
the vehicle tire and positioned in a region of axial extent of the
layer of rubber material of higher electrical conductivity intended
to extend up to the ground contact surface in the finished vehicle
tire;
[0009] subsequently shaping the accumulation of rubber material of
higher electrical conductivity to form a web extending over the
circumference of the vehicle tire, radially outward from the
radially outer surface of the first rubber layer, and having, in
its cross-sectional planes that contain an axis of the vehicle
tire, a predetermined cross-sectional contour;
[0010] subsequently building up a second rubber layer from a
material of relatively lower electrical conductivity on the
radially outer surface of the first rubber layer, adjoining the
shaped web of rubber material axially on both sides; and
[0011] shaping and vulcanizing a tread profile of the vehicle
tire.
[0012] In other words, the objects are achieved according to the
invention by the method for producing a tread for a vehicle
tire--in particular a pneumatic vehicle tire--which is provided
with an electrically conducting layer, which is arranged axially
inside a portion of a first, radially outer rubber layer of the
tread that is formed from a first rubber material, wherein the
electrically conductive layer extends from a second, radially inner
rubber layer of the tread of a second rubber material on the
radially inner side of the tread rubber material up to a ground
contact surface of the tread and wherein both the rubber material
of the electrically conducting layer and the rubber material of the
second, radially inner rubber layer of the tread have a higher
electrical conductivity than the rubber material of the first,
radially outer rubber layer, according to the features of claim 1
that has the following steps:
[0013] building up of a first rubber layer of higher electrical
conductivity, formed such that it extends over the circumference of
the vehicle tire, and building up of an accumulation of rubber
material of higher electrical conductivity, formed such that it
extends over the circumference of the vehicle tire and is arranged
in a positioned manner in the region of axial extent of the layer
of rubber material of higher electrical conductivity that is
intended to extend up to the ground contact surface in the finished
vehicle tire,
[0014] followed by shaping of the accumulation of rubber material
of higher electrical conductivity to form a web which is made to
extend over the circumference of the vehicle tire, radially outward
from the radially outer surface of the first rubber layer, and has
in its cross-sectional planes that contain the axis of the vehicle
tire a predetermined cross-sectional contour,
[0015] followed by building up of a second rubber layer of lower
electrical conductivity on the radially outer surface of the first
rubber layer, which adjoins the shaped web of rubber material of
higher conductivity axially on both sides, and
[0016] shaping and vulcanizing of the tread profile.
[0017] Being formed in this way makes it possible in a simple,
reliable manner to build up and provide electrically conductive
rubber material required for the forming of the web on the first,
likewise electrically conductive rubber layer and, once it has been
dependably provided on the first rubber layer, to shape the layer
of rubber material of higher electrical conductivity individually
in dependence on the individual requirements of the production of
the pneumatic tire that is to be produced. The rubber material of
the second rubber layer is then built up against the shaped web. By
being formed on the first rubber layer and before the second rubber
layer is applied, the web can be individually formed in such a way
that a stable buildup of the layers of the tread rubber can be
dependably ensured along with an optimized contact surface area of
the tire with respect to the surface of the roadway.
[0018] In accordance with an added feature of the invention, the
forming of the accumulation of rubber material of higher electrical
conductivity to form a web which is made to extend over the
circumference of the vehicle tire radially outward from the
radially outer surface of the first rubber layer takes place with a
cross-sectional contour formed such that it tapers from the inside
outward in the radial sense--in particular continuously--in its
cross-sectional planes that contain the axis of the vehicle tire is
particularly advantageous. This allows very great stability of the
web with respect to displacement and tilting during the building up
of the second rubber layer against the web to be achieved in the
tire along with a very narrow contact surface area of the web with
respect to the surface of the roadway.
[0019] In accordance with an additional feature of the invention,
the tapering of the cross-sectional contour profile takes place
with a taper increasing degressively from the inside outward in the
radial sense is particularly advantageous. This allows very great
stability of the web with respect to displacement and tilting
during the building up of the second rubber layer against the web
to be achieved in the tire along with a very narrow contact surface
area of the web with respect to the surface of the roadway.
[0020] In accordance with another feature of the invention, the
forming of the accumulation of rubber material of higher electrical
conductivity to form a web which is made to extend over the
circumference of the vehicle tire radially outward from the
radially outer surface of the first rubber layer takes place with,
in its cross-sectional planes that contain the axis of the vehicle
tire, a cross-sectional contour profile of at least one--in
particular both--axial side faces of the web that is respectively
widened conically from the outside inward in the axial sense toward
the middle of the web is particularly advantageous.
[0021] In accordance with a further feature of the invention, the
building up of the accumulation of rubber material of higher
electrical conductivity takes place during the building up of the
first rubber layer of higher electrical conductivity, formed such
that it extends over the circumference of the vehicle tire, is
particularly advantageous. This makes simple continuous
production--for example by continuous winding--possible with few
operations.
[0022] In accordance with again an added feature of the invention,
the building up of the accumulation of material and the building up
of the first rubber layer, formed such that it extends over the
circumference of the vehicle tire, takes place with the same rubber
material of higher electrical conductivity is particularly
advantageous. This makes particularly simple continuous
production--for example by continuous winding--possible with few
operations.
[0023] In accordance with again an additional feature of the
invention, the building up takes place on a building surface of a
building body that can be driven in a rotational manner about an
axis of rotation; wherein the building body is driven in a
rotational--in particular controlled--manner during the building up
is particularly simple and advantageous. As a result, the rubber
material can be laid on with high accuracy and defined tensile
stress.
[0024] In accordance with again another feature of the invention,
the building body is a building drum, is particularly
advantageous.
[0025] In accordance with again a further feature of the invention,
the building body is a toroidal building core is particularly
advantageous. The built-up tread rubber already corresponds
substantially to the contour in the later tire.
[0026] In accordance with yet an added feature of the invention,
the building surface is formed substantially cylindrically in
relation to the axis of rotation is particularly advantageous.
[0027] In accordance with yet an additional feature of the
invention, the building surface is toroidal is particularly
advantageous.
[0028] In accordance with yet another feature of the invention, the
building surface is part of a solid surface is particularly
advantageous.
[0029] In accordance with yet a further feature of the invention,
the building surface is part of an elastic surface--in particular
of an inflated bladder--is particularly advantageous.
[0030] In accordance with an added feature of the invention, the
building up of the first rubber layer takes place by winding on a
ribbon-shaped rubber strip with a number of turns arranged axially
next to one another or at least partly axially overlapping is
particularly advantageous. This makes an area-covering formation of
the first rubber layer possible by reliable contact in a simple way
and, with deliberate overlapping, additionally makes exact setting
of the volume distribution of the tread rubber along its axial
extent possible with few operations while ensuring the
area-covering distribution of the rubber.
[0031] In accordance with an additional feature of the invention,
the building up of the second rubber layer of lower electrical
conductivity takes place by winding on a ribbon-shaped rubber strip
with a number of turns arranged axially next to one another or at
least partly axially overlapping is particularly advantageous. This
makes an area-covering formation of the second rubber layer
possible by reliable contact in a simple way and, with deliberate
overlapping, additionally makes exact setting of the volume
distribution of the tread rubber along its axial extent possible
with few operations while ensuring the area-covering distribution
of the rubber.
[0032] In accordance with another feature of the invention, the
building up of the accumulation of material takes place by winding
on a ribbon-shaped rubber strip with a number of turns is
particular advantageous. This makes exact setting of the volume
distribution of the accumulation of material possible with only one
operation. In addition, it makes pre-contouring of the accumulation
of material possible.
[0033] In accordance with a further feature of the invention, the
first rubber layer of electrically increased conductivity is built
up radially outside a built-up--in particular toroidally
built-up--carcass ply, in particular of a radial type of
construction, is particularly advantageous.
[0034] In accordance with again an added feature of the invention,
the first rubber layer of electrically increased conductivity is
built up radially outside a breaker belt ply built up radially
outside a built-up--in particular toroidally built-up--carcass
ply--in particular a breaker belt ply assembly comprising one or
more breaker belt plies and a breaker belt bandage--is particularly
advantageous.
[0035] In accordance with again an additional feature of the
invention, the shaping of the accumulation of material, a shaping
body--in particular a contoured shaping body--is brought up
laterally to the flank of the accumulation of material that is
respectively to be shaped and the latter is thereby deformed until
it has the desired contour of the flank of the web to be shaped is
particularly advantageous. This makes individually desired
contouring possible in a simple way with minimal work.
[0036] In accordance with again another feature of the invention,
the shaping body is a baffle along which the accumulation of
material is moved after it has been brought up to said material is
particularly advantageous. This makes simple configuration and
positioning of the shaping body possible.
[0037] In accordance with again a further feature of the invention,
the shaping body is a forming roller or forming roll along which
the accumulation of material is moved after it has been brought up
to said material is particularly advantageous. This makes
individually desired contouring possible in a particularly simple
and reliable way with minimal work.
[0038] In accordance with a concomitant feature of the invention,
the shaping body is a forming ring which is brought up to the
accumulation of material coaxially and radially outside the first
rubber layer and uses an annular--particular contoured--stop to
deform the accumulation of material over the entire circumference
of the first rubber layer is particularly advantageous. This makes
individually desired contouring with exact material alignment over
the entire circumference possible in a simple way. In this case,
springing back of the rubber material of the accumulation of
material can be avoided during the entire rotating movement by the
axial supporting force that is made to extend over the
circumference.
[0039] With the above and other objects in view there is also
provided, in accordance with the invention, a device for producing
a tread of a vehicle tire according to the above outlined method.
The device comprises:
[0040] a building body rotatably mounted about an axis of rotation
for building up rubber layers;
[0041] a drive connection for rotating the building body about the
axis of rotation;
[0042] means for positioning and laying rubber material on the
building body; and
[0043] means for shaping built-up accumulations of rubber material
on the building body and configured to form therefrom a web of
rubber material extending from the radially inner rubber layer to
the ground contact surface of the tread and having a higher
electrical conductivity than the radially outer rubber layer.
[0044] In other words, the device for carrying out the novel method
has a building body mounted rotatably about an axis of rotation for
building up rubber layers, a drive connection for the rotation--in
particular controlled rotation--of the building body about its axis
of rotation, means for the positionable laying--in particular in a
controlled manner--of rubber material on the building body, and
means for shaping built-up accumulations of rubber material on the
building body.
[0045] Other features which are considered as characteristic for
the invention are set forth in the appended claims.
[0046] Although the invention is illustrated and described herein
as embodied in method for producing a tread for a vehicle tire, it
is nevertheless not intended to be limited to the details shown,
since various modifications and structural changes may be made
therein without departing from the spirit of the invention and
within the scope and range of equivalents of the claims.
[0047] The construction and method of operation of the invention,
however, together with additional objects and advantages thereof
will be best understood from the following description of specific
embodiments when read in connection with the accompanying
drawings.
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING
[0048] FIG. 1 shows a pneumatic vehicle tire in cross-sectional
representation;
[0049] FIG. 2 shows a schematic representation of a station for
winding strip-shaped rubber material onto a green tire, with a
green tire built up on a drum and a winding head;
[0050] FIG. 3 shows a schematic sectional representation of the
winding head;
[0051] FIG. 4 shows a simplified schematic representation of the
winding head with method steps represented in FIG. 3a to FIG. 3g to
explain the way in which rubber material is supplied and cut to
length;
[0052] FIG. 5 shows a representation of the process of winding on a
rubber strip to create a tire sidewall and to create a tread
rubber;
[0053] FIG. 6a shows a cross section of the wound-on base of a
tread rubber with an accumulation of material;
[0054] FIG. 6b shows a representation to explain the shaping of a
web from the accumulation of material in a first embodiment;
[0055] FIG. 6c shows a representation of the tread rubber with a
wound-on base and cap;
[0056] FIG. 7 shows a representation to explain the shaping of a
web from the accumulation of material in a second embodiment;
[0057] FIG. 8 shows a representation to explain the shaping of a
web from the accumulation of material in a third embodiment;
[0058] FIG. 9 shows a representation to explain the shaping of a
web from the accumulation of material in a fourth embodiment;
[0059] FIG. 10a shows a cross-sectional representation of a green
tire built up on an expanded shaping bladder to explain the
building up of the tread rubber;
[0060] FIG. 10b shows a cross-sectional representation of a green
tire built up on a toroidal core to explain the building up of the
tread rubber; and
[0061] FIG. 10c shows a cross-sectional representation of a breaker
belt assembly built up on a substantially cylindrical building drum
to explain the building up of the tread rubber.
DETAILED DESCRIPTION OF THE INVENTION
[0062] Referring now to the figures of the drawing in detail and
first, particularly, to FIG. 1 thereof, which illustrates an
exemplary buildup of a pneumatic vehicle tire, in which a first
carcass ply of a carcass 3 of a radial type of construction reaches
around a bead core 27 with a bead filler (not represented any more
specifically) in a right-hand bead region 22 formed for fastening
the pneumatic vehicle tire on a rim, outside an air-impermeable
inner layer over the right-hand shoulder region and the zenith
plane to the bead core 27 with a bead filler that is formed in the
left-hand bead region 22 and around which the ply is laid in the
conventional way. A second carcass ply of the carcass 3, which is
likewise made to extend from the side of the tire represented on
the right in FIG. 1 to the side represented on the left, is laid in
a conventional way over the first carcass ply. In a conventional
way, a bead strip of a known type (not represented any more
specifically), a bead reinforcer of a known type (not represented
any more specifically) and a flange profile 35 are formed in the
bead region 22, and a sidewall rubber material 28, reaching from
the flange profile 35 into the shoulder region, is laid on.
Arranged outside the carcass plies of a radial type of
construction, a number of breaker belt plies of a breaker belt 23
with steel cords embedded in rubber reach over the circumference of
the tire. Additionally formed on the breaker belt plies of the
breaker belt 23, between the breaker belt plies 23 and a tread
rubber 29, is a bandage ply of a known type of the breaker belt 23
with strengthening supports aligned in the circumferential
direction. In the shoulder strip, shoulder strips 31 are
additionally laid on in a known way. The completion of the tire
buildup is formed in a known way by a profiled tread rubber 29.
[0063] The tread rubber 29 is built up in a known way from a
radially outer rubber ply (cap) 33 and a radially inner rubber ply
(base) 32.
[0064] The thickness of the radially inner rubber ply (base) 32 is
at least 0.6 mm. By way of example, it is 2 to 3 mm.
[0065] The radially outer rubber ply (cap) 33 is formed in a known
way with a tread rubber mixture that is suitable for a cap, with a
high proportion of silica, and consequently with a relatively low
electrical conductivity. The radially inner rubber ply (base) 32 is
formed in a known way with a tread rubber mixture that is suitable
for a base, with a high proportion of carbon black, consequently
with a relatively high electrical conductivity in comparison with
the tread rubber mixture that is used for the cap.
[0066] As represented in FIG. 1, to reduce the risks of
electrostatic charges that can occur during driving, there is a web
34 that is made to extend over the entire circumference of the
pneumatic vehicle tire, radially from the radially inner rubber ply
(base) 32 through the radially outer rubber ply (cap) 33 to the
radially outer peripheral surface of the pneumatic vehicle tire,
forming the contact surface with the surface of the road. The web
34 is formed from the same tread rubber mixture from which the
radially inner rubber ply (base) 32 is formed, with a high
proportion of carbon black, and consequently with a relatively high
electrical conductivity in comparison with the tread rubber mixture
used for the cap. In the axial direction A of the pneumatic vehicle
tire, the web 34 extends in its sectional plane with the radially
outer peripheral surface of the radially inner rubber ply (base) 32
over a length of extent a and steadily decreases in its axial
extent outward along its radial extent and, in the sectional plane
with the radially outer peripheral surface of the pneumatic vehicle
tire that forms the contact surface with the road surface, reaches
an axial extent over a length of extent b, where b<a.
[0067] The cross section of the web in a sectional plane that is
represented in FIG. 1 and contains the axis of the pneumatic
vehicle tire has in one embodiment a contour profile with a
progression of the amount of its axial extent that decreases
degressively along its radial extent from the inside outward in the
radial sense.
[0068] To produce the pneumatic vehicle tire, an unvulcanized green
tire without a tread rubber--as represented in FIG. 2--is built up
on a clamping head 2, which is rotatably mounted in a framework 1
and driven in a rotationally controlled manner by means of a
control unit 30, coaxially with respect to the clamping head 2 and
is fastened.
[0069] The green tire comprises--as represented in FIG. 5--the
carcass 3 formed in a conventional way, comprising one or more
plies (not represented) of strengthening supports embedded in
rubber, which are made to extend axially from bead region 22 to
bead region 22 of the green tire and respectively wrapped around
the bead core (not represented any more specifically for purposes
of simplification) with a bead filler built up on it. In a
conventional way, a bead strip of a known type (not represented any
more specifically), a bead reinforcer of a known type (not
represented any more specifically) and a flange profile (not
represented in FIG. 5 for purposes of simplification) are formed in
the bead region 22. A breaker belt 23 with a number of breaker belt
plies (not represented in FIG. 5 for purposes of simplification)
and one or more bandage plies built up on said breaker belt reach
over the circumference of the tire, arranged outside the carcass
plies of a radial type of construction.
[0070] The green tire is toroidally formed and fastened on the
clamping head 2.
[0071] In FIG. 2, a winding head 4 is additionally represented. For
winding onto a new tire sidewall, rubber material 20 in the form of
a round cord or ribbon is drawn out of an extruder 21 of a known
type over a roller carrier that is fastened to the winding head 4
and has conveying rollers 19 mounted rotatably one behind the other
in the conveying direction in a frame 13 of the roller carrier, and
following that through between two holding plates 16 and 17, which
are respectively fastened to a reciprocating piston 14 or 15 of a
pneumatically or hydraulically actuable reciprocating piston
cylinder, actuated in a controlled manner by the control unit 30,
in a frame 13 mounted displaceably in the winding head 4, following
that through between two reciprocating pistons of a reciprocating
piston cylinder of a cutting device 9 that can respectively be
actuated hydraulically or pneumatically and are actuated in a
controlled manner by the control unit 30, each provided with a
reciprocating piston cutter 10 or 11, and through between two
calender rolls 7 and 8 of a forming calender 6 that are arranged
downstream in the conveying direction, interact with each other and
are driven in a rotationally controlled manner by the control
device 30, said rubber material being drawn by the calender rolls,
and conveyed further over deflecting rollers of a known type onto a
downstream laying roller 5. By means of the laying roller 5, the
ribbon-shaped material shaped by the profiled calender rolls 7 and
8 of the forming calender 6 is rolled up under pressure--as can be
seen in FIG. 1 and FIG. 4--onto the carcass of the green tire
between the bead region 22 and the tread of the tire to be
produced.
[0072] For this purpose, firstly the winding head 4 is displaced
parallel to the axis of rotation of the clamping head 2 in the x
direction represented in FIGS. 2 and 3 to the extent that the
laying roller 5 comes into contact with the green tire. By stepless
displacement under the control of the control unit 30 and by means
of a known displacing device (not represented) in the coordinate
direction x parallel to the axis of rotation of the clamping head 2
and the coordinate direction y perpendicular to the axis of
rotation of the clamping head 2, the winding head 4 can in this
case be respectively positioned in such a way that the laying
roller 5 is in contact with the green tire 3 with the desired
pressure. In addition--as represented in FIG. 3--the winding head 4
can be steplessly pivoted in a controlled manner about axis z
aligned perpendicularly to the x-y plane in a known way that is not
represented, so that the winding head 4 can be respectively
positioned by means of the control unit 30 such that the laying
roller 5 respectively assumes with its peripheral surface the
alignment desired for winding on with respect to the surface of the
green tire.
[0073] As a result--as represented in FIG. 5--the rubber material
20 shaped by the calender rolls 7 and 8 is continuously wound onto
the carcass from the inside outward in the radial sense during the
controlled rotation of the green tire about the axis of rotation of
the clamping head 2. The individual turns may in this case be wound
out next to one another or else, if need be, also overlapping one
another. This is possible by corresponding advancement of the
movement of the winding head 4 in the x-y plane along the contour
of the toroidal green tire. If need be, for this purpose the
alignment of the laying roller 5 in relation to the surface of the
contour of the toroidal green tire is continuously corrected by
controlled pivoting of the winding head 4 about the z axis.
[0074] If required, in an embodiment that is not represented, the
laying roller 5 is additionally formed such that it is steplessly
displaceable in a controlled manner in the z direction. In the case
of such an embodiment, the winding-on position of the laying roller
5 with respect to the green tire can also be set in an individually
controlled manner in the z direction or changed during the
winding.
[0075] As soon as the rubber material in the form of a round cord
or ribbon that is drawn between the reciprocating piston cutters 10
and 11 has reached such a length that it corresponds to the
winding-on length desired for the production of the sidewall of the
green tire, a cutting process is initiated by control unit 30. For
this purpose, the reciprocating pistons of the reciprocating piston
cutters 10 and 11 are pneumatically or hydraulically displaced
toward each other in the respective reciprocating piston cylinder
and, as a result, the rubber material in the form of a round cord
or ribbon is cut up by the reciprocating piston cutters 10 and 11
acting from both sides.
[0076] As soon as the end of the cut-off rubber strip that is
created by the cutting process has been pressed by the laying
roller 5 onto the sidewall of the green tire, the winding head is
removed from the green tire by controlled displacement in the x-y
plane.
[0077] For winding onto a new tire sidewall, a new green tire is
mounted on the clamping head 2 and the winding head 4 is in turn
brought up to the green tire in a controlled manner to the extent
that the winding process for building up the tire sidewall can be
initiated.
[0078] To introduce the beginning of a rubber strand in the form of
a round cord or ribbon newly created by the extruder between the
calender rolls 7 and 8, firstly the reciprocating pistons 14 and 15
are moved hydraulically or pneumatically under the control of the
control unit 30 toward each other to the extent that the holding
plates 16 and 17 aligned parallel to the rubber ribbon 20
respectively come into frictional contact with the rubber ribbon 20
and firmly hold the rubber ribbon 20 between them. After that,
under the control of the control unit 30, the frame 13, which is
mounted displaceably in the winding head 4 parallel to the
conveying direction of the rubber ribbon 20, is moved in the
conveying direction toward the calender rolls 7 and 8 of the
forming calender 6, so that the rubber ribbon 20 is introduced
between the calender rolls 7 and 8 and is drawn in by the calender
rolls 7 and 8 through the calender gap between the calender rolls 7
and 8. This state is represented in FIG. 4a. After that--as can be
seen in FIG. 4f--the contact between the holding plates 16 and 17
and the rubber strip is in turn brought to an end by hydraulic
actuation of the reciprocating pistons 14 and 15 perpendicularly to
the conveying direction of the rubber ribbon 20 away from the
rubber material. After that--as represented in FIG. 4g--the frame
13 is in turn raised into its starting position.
[0079] For cutting, firstly the reciprocating pistons 14 and 15 are
moved hydraulically or pneumatically under the control of the
control unit 30 toward each other to the extent that the holding
plates 16 and 17 aligned parallel to the rubber ribbon 20
respectively come into frictional contact with the rubber ribbon 20
and firmly hold the rubber ribbon 20 between them. After that,
under the control of the control unit 30, the frame 13, which is
mounted displaceably in the winding head 4 parallel to the
conveying direction of the rubber ribbon 20, is moved at the
conveying speed of the calender rolls 7 and 8 in the conveying
direction toward the calender rolls 7 and 8 of the forming calender
6, so that the rubber ribbon 20 is led in the direction of the
calender gap formed between the calender rolls 7 and 8, wherein the
rubber ribbon 20 continues to be drawn in by the calender rolls 7
and 8 through the calender gap between the calender rolls 7 and 8.
This state is represented in FIG. 4a. After that, the frame 13 is
moved back again in a controlled manner in the counter conveying
direction. The rubber ribbon 20 respectively clamped between the
holding plates 16 and 17 and between the calender rolls 7 and 8 is
thereby stretched between the two clamping positions. This produces
a constriction of the rubber ribbon 20. The position of the
reciprocating piston cutters 10 and 11 in the winding head 4 is
chosen in this case such that they are positioned in the region of
the expected thinnest cross section of the stretched material. This
is represented in FIG. 4b. After that--as can be seen in FIG.
4c--the reciprocating piston cutters 10 and 11 are moved
hydraulically or pneumatically in a controlled manner toward each
other, so that the rubber ribbon 20 is severed in the region of the
thinnest cross section. The end of the preceding strip material is
conveyed further to the green tire. As can be seen in FIG. 4d, the
beginning of the next strip material is also of a tapered form
and--as can be seen in FIG. 4e--is introduced into the calender gap
between the calender rolls 7 and 8 by displacing the frame 13 in
the conveying direction. After that--as can be seen in FIG. 4f--the
contact between the holding plates 16 and 17 and the rubber strip
is in turn brought to an end by hydraulic actuation of the
reciprocating pistons 14 and 15 perpendicularly to the conveying
direction of the rubber ribbon 20 away from the rubber material.
After that--as represented in FIG. 4g--the frame 13 is in turn
raised into its starting position.
[0080] As can be seen in FIG. 4c, the end of the preceding strip is
also of a tapered form. The tapering of the beginning and end of
the rubber strip makes it possible when winding onto the surface of
the green tire at the beginning and at the end to obtain a uniform
transition with the surface of the green tire.
[0081] To determine the length of the rubber strip material for
correctly cutting to the length to be wound on, in one embodiment
the length is determined from the available data on the conveying
speed, which is determined for example from the rotational speed of
the calender rolls 7 and 8 or is measured directly, and the
conveying time. In an alternative embodiment--as represented in
FIG. 2--the length of the conveyed rubber strip material is
measured by means of sensors 31 formed in the winding head for
determining a rubber ribbon of a known type and these data are
passed on to the control unit for processing. The sensors are
arranged for example between the cutting device with reciprocating
cutters 10 and 11 and the forming calender 6 with the calender
rolls 7 and 8 or else--as represented in FIG. 2--the calender in
the conveying direction.
[0082] As represented in FIG. 5, the tread rubber mixtures for
building up the radially inner rubber ply (base) 32 and the
radially outer rubber ply (cap) 33 of the tread rubber 29 of the
tire are also wound on by means of a winding head 4--as represented
above--from a rubber strip produced in a correspondingly identical
way, over a laying roller 25 of the winding head 4. Represented in
this respect in FIG. 5 is an embodiment in which the rubber strip
is wound onto a breaker belt 23 of a known type built up onto the
carcass of the green tire. Instead of the radial movement along the
sidewall contour, the laying takes place with a controlled axial
movement along the contour of the pneumatic vehicle tire in the
region of the tread rubber. During the controlled rotation of the
green tire about the axis of rotation of the clamping head 2, the
rubber material 20 shaped by the calender rolls 7 and 8 is
continuously wound onto the breaker belt 23 in the axial direction
A along the axial extent of the breaker belt. The individual turns
may in this case be wound out next to one another or else, if need
be, also overlapping one another. This is possible by corresponding
advancement of the movement of the winding head 4 in the x-y plane
along the contour of the toroidal green tire. If need be, for this
purpose the alignment of the laying roller 5 in relation to the
surface of the contour of the toroidal green tire is continuously
corrected by controlled pivoting of the winding head 4 about the z
axis.
[0083] It is possible to form different thicknesses of the built-up
plies of the tread rubber and/or of the sidewall respectively by
controlled changing of the advancement of the winding head along
the tire contour to be wound onto, and consequently by deliberate
different overlapping of the individual turns of the wound strip
material formed next to one another.
[0084] For this purpose, the contouring and thickness distribution
can in addition be influenced in a controlled manner by
deliberately changing the angle of alignment of the laying roller 5
or the laying roller 25 in relation to the surface of the green
tire.
[0085] It is similarly possible to wind the built-up plies of the
tread rubber or the sidewall on from a number of such rubber
strips. In this case, these rubber strips may, if need be, be of
different rubber material and/or differently shaped. The different
shaping takes place for example by modified calender rolls 7 of the
forming calender.
[0086] In one embodiment, the shoulder strip 31 is wound on
together with the sidewall as a joint component, in another
embodiment the shoulder strip 31 is wound on as an independent
component following the formation of the sidewall 28 and the tread
rubber 29.
[0087] FIG. 6a schematically shows the winding pattern of a base
ply 32 formed in this way by winding from a rubber ribbon 24
produced from a base mixture of high electrical conductivity--for
example with a high proportion of silica. In the case of this
exemplary embodiment, the base ply 32 is produced from left to
right over the entire axial extent of the breaker belt plies (not
represented), with overlapping of the individual neighboring turns,
lying next to one another, of the rubber ribbon 24 wound on
helically about the axis of the green tire. As this happens,
controlled changing of the advancement of the winding head in the
axial direction A of the green tire has the effect in the axial
region of extent of the web 34 that is wanted in the tread rubber
of the finished vehicle tire of an increased winding density of the
rubber ribbon 24 in comparison with the other axial regions of
extent, and consequently the effect of forming an accumulation of
material 26.
[0088] Subsequently--as represented in FIG. 6b--two contoured
rollers 35 and 36, which are respectively mounted rotatably in the
framework 1 of the winding head 4, for example on levers that are
movable in a controlled manner (not represented any more
specifically), or fed in by a suitable separate device of a known
type that is not represented, are moved in the axial direction
toward the accumulation of material 26 from both axial sides of the
accumulation of material 26 until they respectively come into
contact with the accumulation of material 26. In a way
corresponding to the desired contour of the web 34 to be formed,
the contoured rollers 35 and 36 are then moved further in a
controlled manner axially inward and radially outward and at the
same time driven in a controlled manner about their axis of
rotation. The pressure exerted on the accumulation of material 26
by the driven rollers 35 and 36 brings about deliberate deformation
of the accumulation of material 26. The controlled axial movement
in the axial and radial directions of the green tire with
simultaneous controlled rotational movement of the built-up green
tire about its axis has the effect that the accumulation of
material is deformed over the entire circumferential extent of the
green tire into the desired cross-sectional contour of the web 34
that is to be formed. The drive of the contoured rollers 35 and 36
about their own axis makes further deliberate influencing of the
distribution of material possible.
[0089] In another embodiment, the contoured rollers 35 and 36 are
formed such that they are merely mounted in a freely rotatable
manner and not themselves driven. Here, their rotational movement
takes place merely by means of the frictional contact with the
accumulation of material 26.
[0090] The cross-sectional contour of the contoured rollers 35 and
36 is formed individually to the corresponding requirements of the
desired contouring of the web 34.
[0091] In a special embodiment, the solid angles of the axis of
rotation of the contoured rollers 35 and 36 in relation to the axis
of rotation of the green tire is likewise changed in a controlled
manner.
[0092] For the sake of simplicity, the contours of the individual
turns of the radially inner ply 32 (base) are not represented in
FIG. 6b, but merely the enveloping outer contour of the radially
inner ply 32 (base) and the cross-sectional contour of the web 34
shaped by the contoured rollers 35 and 36.
[0093] The web 34--in the form represented in FIG. 6b--is formed in
the sectional plane with the radially outer peripheral surface of
the radially inner ply 32 (base) with its cross-sectional contour
having an axial length of extent a. The cross-sectional contour of
the web 34 is formed along the radial extent of the green tire from
the inside outward in the radial sense with a degressively
decreasing length of extent. In the radial position of the maximum
radially outer extent of the web 34, the latter extends in the
axial extent only over an axial length of extent b, where
b<a.
[0094] As can be seen in FIG. 6c, following the shaping of the web
34 by means of the contoured rollers 35 and 36, the radially outer
rubber ply (cap) 33 is wound onto the radially inner rubber ply
(base) 32 by winding on a ribbon-shaped rubber strip 24 of a rubber
mixture that is suitable for the cap, of high electrical
conductivity--for example with a high proportion of carbon
black--respectively with overlapping of the neighboring turns from
the axial outside, from the respective tire shoulder side, to the
axial inside, toward the web 34, helically about the axis of
rotation of the green tire, wherein the radially outer contour of
the radially outer ply (cap) 33 of the tread rubber is created by
controlled overlapping of the respectively neighboring turns. With
its radially outer peripheral contour in the radially outer
position of its extent, with the axial length of extent b, the web
34 is in the same radial position as the two axially adjacent
wound-on radially outer regions of extent of the radially outer
tread rubber ply (cap) 33, with its radially outer adjacent
peripheral contour, and forms an integrated part of the radially
outer peripheral contour of the radially outer tread rubber ply
(cap) 33.
[0095] In FIG. 7, an alternative way of producing the accumulation
of material 26 to form the web 34 is represented. When produced in
this way, the radially inner tread rubber ply (base) 32 is laid on
in the axial direction of extent as in the exemplary embodiment of
FIG. 6a, right through from one shoulder to the other shoulder,
from a ribbon-shaped rubber strip 24 of a suitable base mixture,
with controlled overlapping of the respectively axially neighboring
turns. Following that, in the axial region of extent of the desired
formation of a web 34, a ribbon-shaped rubber strip 24 is built up
in the form of a number of turns wound on spirally radially one on
top of the other. The shaping to form the web 34 takes place in the
way explained with reference to FIG. 6b. In FIG. 8, a further
alternative for producing the accumulation of material 26 and the
web 34 is represented. Here, as represented in the example of FIG.
7, firstly the radially inner tread rubber ply (base) is built up
from a ribbon-shaped rubber strip 24 of a suitable base mixture by
helical winding on about the axis of the green tire in the axial
direction from left to right of the entire axial extent of the
breaker belt, with overlapping of the respectively neighboring
turns. In a second step, a ribbon-shaped rubber strip 24 of a
suitable cap mixture is wound on helically about the axis of the
green tire from the right-hand side, from the right side of the
breaker belt represented in FIG. 8, inward in the axial direction
to the position of the desired web formation, with overlapping of
the respectively neighboring turns, to form the right-hand cap
side. After that, a ribbon-shaped rubber strip 24 of the base
mixture is built up on the built-up radially inner tread rubber ply
(base) 32 in the position of the desired web formation in direct
axial contact with the neighboring turn of the built-up side of the
radially outer tread rubber ply (cap) 33 in the form of a number of
spirally wound-on turns arranged radially one on top of the other.
As described with respect to FIG. 6b, from the axial side of the
accumulation of material 26 that is facing away from the already
wound-on side of the radially outer tread rubber ply (cap) 33 and
has a contoured roller 36, the contoured roller 36 is moved in a
controlled manner against the accumulation of material 26 and the
accumulation of material 26 is consequently deformed into the
desired web contour by the forces acting axially on the
accumulation of material 26 from the contoured roller 36 that is
moved in a controlled manner and from the built-up side of the
radially outer tread rubber ply (cap), and the web 34 is formed in
this way. Following that, on the axial side that is represented on
the left in FIG. 8, the radially outer tread rubber ply (cap) 33 is
helically wound on from the ribbon-shaped rubber strip 24 of
suitable cap mixture, from the left-hand side of the breaker belt
in the axial direction to the web 34, with overlapping of the
neighboring turns.
[0096] FIG. 9 shows a further embodiment for the shaping of a web
34 from a produced accumulation 26--corresponding to the
embodiments already explained--of the radially inner tread rubber
ply (base) 32. In this case, after building up the inner tread
rubber ply (base) 32 with an accumulation of material 26
concentrically in relation to the clamping head 2, a forming ring
38, which is formed on one end face with an end face contour 39
corresponding to the contour of a flank of the web 34 to be shaped,
is moved with this end face axially in the direction of the
accumulation of material 26. The contoured ring 38 is in this case
formed in its inside diameter in such a way that it can be
displaced with radial play over the outer contour of the built-up
radially inner tread rubber ply (base) 32 in the axial region of
extent outside the accumulation of material 26 up to the
accumulation of material 26 and that the radial region of extent of
the contoured end face 39 also takes up the radial region of extent
of the web 34 that is to be formed. The contoured ring 38 is in
this case pushed so far over the built-up radially inner tread
rubber ply (base) 32 that the contoured end face 39 comes into
contact with the accumulation of material 26 and deforms the
accumulation of material 26 to such an extent that it is provided
on the axial side facing the end face 39 with the contour profile
of the flank of the web 34 that is to be formed. After that, the
contoured ring 38 is removed again axially from the region of
extent of the built-up radially inner tread rubber ply (base) 32.
After that, the second axial side of the accumulation 26 is
deformed into the desired contour of the second flank of the web by
a correspondingly formed further contoured ring 38 (not
represented), which is pushed over the green tire from the other
axial side.
[0097] In another embodiment, the two contoured rings 38 and 39 are
pushed over the green tire from the axial outside simultaneously,
and consequently exert deforming forces on the accumulation of
material 26 simultaneously from the two axial sides until the
desired web is provided with the desired contour on both its
flanks. After that, the two rings 38 are removed from the green
tire outward in the axial sense. The radially outer tread rubber
ply (cap) 33 is built up--as described in connection with FIG.
6c.
[0098] In another embodiment that is not represented, while the
first contoured ring 38 is in contact with the accumulation of
material 26, a contoured roller 35 has been brought up to the
accumulation of material 26 instead of the second contoured ring 38
from the axial side of the accumulation of material 26 that is
opposite from the first contoured ring--as explained in connection
with FIG. 6b. Consequently, deforming forces are exerted on the
accumulation of material 26 simultaneously from the two axial sides
until the desired web is provided with the desired contour on both
its flanks. After that, the contoured ring 38 and the contoured
roller 35 are removed from the green tire outward in the axial
sense. The radially outer tread rubber ply (cap) 33 is built up--as
described in connection with FIG. 6c.
[0099] In another embodiment that is not represented, the radially
inner rubber ply (base) 32 is built up as described in connection
with FIG. 7a. After that, a contoured ring 38 is moved into the
desired axial position of a web flank that is to be shaped. After
that, the accumulation of material 26 in axial contact with the
contoured surface 39 of the contoured ring 38 is wound onto by a
number of turns arranged one on top of the other in the radial
direction. After that--as explained in connection with FIG. 6b--a
contoured roller 35 is brought up to the accumulation of material
26 from the axial side of the accumulation of material 26 that is
opposite from the contoured ring 38, to the extent that the
accumulation of material is shaped between the contoured ring 38
and the contoured roller 35. In this case, deforming forces are
exerted on the accumulation of material 26 simultaneously from the
two axial sides until the desired web is provided with the desired
contour on both its flanks. After that, the contoured ring 38 and
the contoured roller 35 are removed from the green tire outward in
the axial sense. The radially outer tread rubber ply (cap) 33 is
built up--as described in connection with FIG. 6c.
[0100] The green tire produced in this way, as in the various
embodiments in connection with the embodiments explained with FIGS.
5 to 8, with a radially inner tread rubber ply (base) 32 and a
radially outer tread rubber ply (cap) 33, with the web 34 made to
extend through the radially outer tread rubber ply (cap) 33, is
removed from the clamping head in a known way (not represented any
more specifically) and fed to a vulcanizing press of a known type
(not represented any more specifically), in which it is vulcanized
while shaping the tread rubber profiling and the sidewall
design.
[0101] Instead of the aforementioned clamping head 2, in an
alternative way of producing the green tire it is also built up on
a tire building drum of a known type for having the tread rubber
and/or sidewalls wound on.
[0102] As represented in FIG. 10a, in one embodiment the green tire
3 is built up on a toroidally expanded bladder 40, for example a
shaping bladder, for having the tread rubber and/or sidewalls wound
on. The winding operation for building up the tread rubber and/or
the sidewalls takes place as explained in the aforementioned
exemplary embodiments.
[0103] As represented in FIG. 10b, in another embodiment the green
tire 3 is built up on a toroidally formed fixed building core 41,
for having the tread rubber and/or sidewall wound on. The winding
operation for building up the tread rubber and/or the sidewalls
takes place as explained in the aforementioned exemplary
embodiments.
[0104] In the embodiment represented in FIG. 10c, the breaker belt
plies of a breaker belt 23 are built up on a belt building drum 42
of a known type, with a substantially cylindrically formed radially
outer surface. In the same way as explained in the embodiments with
respect to FIGS. 5 to 9, the radially inner tread rubber ply (base)
32 and an accumulation of material 26 are wound onto the breaker
belt 23 helically around the belt building drum 42. As explained in
connection with FIGS. 5 to 9, a web 34 of the desired contour is
shaped from the accumulation of material 36 and the radially outer
tread rubber ply (cap) is helically wound on. The tread
rubber/breaker belt assembly prefabricated in this way, comprising
the breaker belt 23 and the tread rubber, is removed in a known way
(not represented any more specifically) from the belt building drum
42 and laid onto a carcass assembly, which is built up on a carcass
building drum of a known type (not represented) from the component
parts for forming the bead region with the bead core, bead filler,
bead reinforcing strip and other desired components for building up
the bead region, the inner layer and the carcass ply, and is
toroidally shaped, and said tread rubber/breaker belt assembly is
connected to said carcass assembly in a known way.
[0105] In one embodiment, in the course of the production of the
carcass assembly on a flat carcass building drum of a known type,
the sidewalls are wound on the carcass with a winding head formed
as explained with respect to FIGS. 2 to 4, or built up in a
conventional way.
[0106] In another embodiment, after toroidal elevation and before
joining together with the breaker belt assembly, the sidewall is
wound onto the carcass in the way described in connection with the
explanations with respect to FIGS. 2 to 4 or laid on in a
conventional way.
[0107] In another alternative embodiment, after joining the tread
rubber/breaker belt assembly together with the toroidally shaped
carcass assembly, the sidewall is wound on in the way described in
connection with the explanations with respect to FIGS. 2 to 4 or
laid on in a conventional way.
[0108] The rubber mixture of high electrical conductivity that is
used for the radially inner tread rubber ply (base) 32 and for
forming the accumulation of material 26 is for example a rubber
mixture that has after vulcanization a resistivity of no more than
10.sup.6 .OMEGA.cm at 25.degree. C. The rubber mixture of low
electrical conductivity that is used for forming the radially outer
tread rubber ply (cap) 33 is for example a rubber mixture that has
after vulcanization a resistivity of 10.sup.8 .OMEGA.cm at
25.degree. C.
[0109] The axial position of the web 34 is chosen such that the web
34 is formed in the axial region of extent of radially raised
profile elements, for example circumferential ribs or rows of
profile blocks, of the intended tread rubber profile and is in
definite contact with the road surface during the rolling of the
pneumatic vehicle tire.
[0110] In one embodiment, instead of the aforementioned singly
formed web 34, such a web 34 is formed in two or three different
axial positions of the tread rubber profile.
[0111] In an embodiment that is not represented, the radially inner
tread rubber ply (base) 22 of high electrical conductivity is
formed by a number of plies arranged radially one on top of the
other and respectively built up by the aforementioned winding
technique.
[0112] In another embodiment that is likewise not represented, the
radially outer tread rubber ply (cap) 33 of low electrical
conductivity is formed by a number of plies arranged radially one
on top of the other and respectively built up by the aforementioned
winding technique.
[0113] In a further embodiment that is likewise represented, both
the radially inner tread rubber ply (base) 32 of high electrical
conductivity and the radially outer tread rubber ply (cap) 33 of
lower electrical conductivity are respectively formed by a number
of plies arranged radially one on top of the other and respectively
built up by the aforementioned winding technique.
[0114] As can be seen in FIGS. 6a and 9, the accumulation of
material 26 is already pre-contoured in the form of a mound or
triangle by the winding technique used there for creating the
accumulation of material 26. In another embodiment--as represented
in FIG. 7--the accumulation of material 26 is formed with
rectangular pre-contouring.
[0115] In the case of the embodiments described and represented in
FIGS. 6, 7 and 9, during the winding on of the radially outer tread
rubber ply (cap) 34 from a tire shoulder in the direction of the
shaped web, in an alternative embodiment the contoured roller 36
used for shaping or the forming ring 38 that was used for shaping
the web 34 from the axially opposite side has been left in contact
with the web 34, so that, during the winding on of the radially
outer rubber ply (cap) against the web 34, the web 34 is axially
supported by the contoured roller 36 or the forming ring 38 from
the axial side opposite from this winding on. After that, the
radially outer tread rubber ply (cap) 33 is wound axially in the
direction of the web from the opposite tire shoulder, wherein,
during the winding on against the web 34, the latter is axially
supported by the already wound-on side of the radially outer tread
rubber ply (cap) 33.
[0116] Instead of the contoured rollers 35 and 36 mentioned for
forming the contouring in the above embodiments, in an alternative
embodiment contoured profiled rolls or contoured baffles are
used.
[0117] In a further embodiment, a colored (yellow, red, green,
blue) base rubber mixture of high electrical conductivity is used
at least for building up the accumulation of material. In this way,
the web formed in the finished pneumatic vehicle tire stands out as
colored differently from the surrounding rubber material of the
radially outer tread rubber ply (cap).
[0118] The web 34 is of a straight form in the circumferential
direction of the pneumatic vehicle tire. In another embodiment, it
may be of a wavy form along the circumferential extent. This is
possible by controlled forming of the profiled rolls, profiled
rollers or baffles used for the configuration of the web 34, with
changed pressing force over the circumference of the green
tire.
[0119] The cross section of the web 34 is formed such that it is
symmetrically triangular in its base contour and perpendicular to
the inner tread rubber ply (base) 32, with a degressively
decreasing axial extent in the radial direction from the inside
outward--as represented above. In another embodiment, the base
contour is a rectangular parallelogram or mushroom-shaped,
depending on the individually desired profile to be contoured.
[0120] As represented in FIG. 8, in another embodiment the web is
not formed perpendicular to the inner tread rubber ply (base) 32,
but with a deliberately obliquely inclined contouring.
[0121] In a further embodiment, after building up of the cap, the
web radially reaches slightly beyond the radial extent of the cap
and is rolled on the radial outer surface of the cap by
non-illustrated pressing rollers.
* * * * *