Title of Invention

METALLIC CORD, RUBBER/CORD COMPOSITE OBJECT AND PNEUMATIC TIRE OBTAINED USING THE SAME

Abstract A rubber-cord complex 9 having an improved wet heat adhesive property between a rubber and a cord comprising a drawn plated wire, and including a cord 10 comprising a drawn plated wire 17 prepared by providing a brass plated layer 16E on the surface of an element wire 15 and drawing the resulting plated wire, and a rubber 12 vulcanized and bonded to the cord 10, wherein the rubber-cord complex 9 has an adhesion reaction layer 25 formed by a cross-linking reaction of sulfur and copper, between the rubber 12 and the brass plated layer 16E, and in a wet heat deterioration state after being subjected to the vulcanization to bond the rubber 12 thereto and further held under an atmosphere having a temperature of 50 to 100°C and a humidity of 60 to 100% for one hour to 20 days, the adhesion reaction layer 25 has an average thickness of 50 to 1, 000 nm, and the interface S between the adhesion reaction layer 25 and the rubber has a fractal dimension of 1.001 to 1.300.
Full Text Description
Title of the Invention: METAL CORD, RUBBER-CORD COMPLEX AND
PNEUMATIC TIRE USING THE SAME
TECHNICAL FIELD
The present invention relates to a metal cord and a
rubber-cord complex in which an adhesion reaction layer formed
between a rubber and a brass plated layer of a plated element
wire is specified to thereby suppress deterioration in
adhesiveness between the plated wire and the rubber under a wet
heat environment, and a pneumatic tire using the complex.
BACKGROUND ART
As a reinforcing element for rubber products such as
pneumatic tires, hoses and industrial belts, a metal cord has
been popularly used from the viewpoints of good reinforcing
effect and the like. In a rubber-cord complex such as a rubber
product reinforced with such a metal cord, the surface of element
wires of the cord is plated with brass containing copper and
zinc in order to enhance the adhesive property of the metal cord
to the rubber. Typically, this brass plating is performed in
such a manner as sequentially forming a copper plated layer and
a zinc plated layer on the surface of an element wire and then
subjecting them to thermal diffusion to give an alloy of the

two metals.
It is known that the adhesive property between the brass
plated layer and the rubber is revealedby formation of an adhesion
reaction layer between the brass plated layer and the rubber
through a cross-linking reaction which occurs between copper
in the brass plated layer and sulfur incorporated into the rubber
during vulcanization of the rubber.
DISCLOSURE OF INVENTION
Problem to be Solved by the Invention
However, although a conventional brass plating has a good
adhesive property in an initial stage after the vulcanization
(initial adhesive property), it tends to be poor in wet heat
adhesive property such that the adhesive property decreases under
a wet heat environment at high temperature and high humidity
and the brass plating is more likely to separate from the rubber.
It is effective for improving the wet heat adhesive property
to add an organocobalt salt to the rubber. However, the
organocobalt salt is expensive, and has a property of making
an unvulcanized rubber apt to deteriorate or thermally
deteriorate. Hence the amount of the organocobalt salt to be
incorporated is limited, so a sufficient increase in wet heat
adhesive property is not achieved thereby.
As other technologies to improve the wet heat adhesive
property are known, for example, a method of suppressing

diffusion of copper into rubber, as disclosed in JP-A- 2 003 -096 5 94,
wherein the content of copper in the brass plated layer is limited
to 62% or less to suppress excessive formation of a sulfide at
the interface with the rubber, and a method of suppressing
corrosion reaction and adhesion reaction at the interface with
the rubber, as disclosed in JP-A-2003-094108 and JP-B-1812616,
by plating a ternary alloy of copper, zinc and nickel as a brass
plating. However, in these methods, no investigation about
structure of plated layer (structure of reaction layer) optimum
to improvement of wet heat adhesive property has been made from
the viewpoint of mechanism of wet heat deterioration. As a result,
the effects are limitative and do not reach a practical level.
In view of such circumstances, the present inventors
conducted an intensive study and, as a result, they have found
that the adhesive property under the wet heat environment can
be exhibited on a higher level as compared with a conventionally
achieved adhesive property when the state of irregularity of
the interface between the adhesion reaction layer and the rubber
and the average thickness of the adhesion reaction layer fall
within specific ranges.
Accordingly, a primary object of the present invention
is to provide a rubber-cord complex having a wet heat adhesive
property improved basically by specifying the state of
irregularity of the interface between the adhesion reaction layer
and the rubber and the average thickness of the adhesion reaction

layer.
A second object of the present invention is to provide
a metal cord suitable for use in the rubber-cord complex and
capable of improving its wet heat adhesive property to a rubber
vulcanized and adhered thereto.
A third object of the present invention is to provide a
pneumatic tire with its durability improved by the use of the
rubber-cord complex as mentioned above.
Means to Solve the Problem
The present invention as claimed in claim 1 is directed
to a rubber-cord complex obtained by vulcanizing a rubber to
adhere it to a metal cord comprising a drawn plated wire prepared
by providing a plated layer of brass containing copper and zinc
on the surface of a metal wire and drawing the resulting plated
wire, wherein:
the rubber-cord complex has an adhesion reaction layer
formed by a cross-linking reaction of sulfur in the rubber and
copper in the brass plated layer, between the rubber and the
brass plated layer, and
in the wet heat deterioration state of the metal cord to
which the rubber has been vulcanized and bonded and which has
been held in an atmosphere having a temperature of 50 to 100°C
and a humidity of 6 0 to 100% for one hour to 2 0 days, the average
thickness of the adhesion reaction layer is from 50 to 1,000

nm , and the interface between the adhesion reaction layer and
the rubber has a fractal dimension of 1.001 to 1.300.
The invention as claimed in claim 5 is directed to a metal
cord for use in the rubber-cord complex according to claims 1
to 3 , wherein the brass plated layer is formedby thermal diffusion
of a copper plated layer and a zinc plated layer formed by plating
in layers on a metal wire, in which the copper plated layer is
formed by plating at a current density of 15 to 25 A/dm2, the
zinc plated layer is formed by plating at a current density of
40 to 60 A/dm2, and the thermal diffusion is conducted by a low
temperature diffusion at a temperature of 500 to 550°C.
The invention as claimed in claim 6 is directed to a metal
cord for use in the rubber-cord complex according to claims 1
to 3 , wherein the brass plated layer is formedby thermal diffusion
of a copper plated layer and a plated layer of a zinc alloy selected
from a zinc-nickel alloy and a zinc-cobalt alloy, the layers
being formed in layers on a metal wire, in which the copper plated
layer is formed by plating at a current density of 15 to 25 A/dm2,
the zinc alloy plated layer is formed by plating at a current
density of 40 to 60 A/dm2, and the thermal diffusion is conducted
by a low temperature diffusion at a temperature of 500 to 550°C.
The invention as claimed in claim 7 is directed to a
pneumatic tire in which the rubber-cord complex according to
claims 1 to 4 is used as a ply for tire reinforcement.

Effects of the Invention
As stated above, in the present invention, the irregularity
of the interface between a rubber and an adhesion reaction layer
in which sulfur in the rubber and copper in a brass plated layer
bond to each other by a cross-linking reaction, is increased
and complicated such that the fractal dimension of the interface
falls within the range of 1.001 to 1.3 00. Also, the average
thickness of the adhesion reaction layer is properly secured.
As a result, the bonding force to the rubber at the interface
of the adhesion reaction layer can be sufficiently increased
and, in addition, increase in strength of the adhesion reaction
layer itself can be achieved. Thus, by a synergistic effect
of them, improvement in wet heat adhesive property between the
rubber and the cord can be achieved.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a cross sectional view showing an example of
pneumatic tires in which a rubber-cord complex of the present
invention is used as a ply for tire reinforcement;
FIG. 2 is a cross sectional view showing the ply mentioned
above which is the rubber-cord complex;
FIG. 3A is a view explaining steps to form a brass plated
layer of a binary alloy;
FIG. 3B is a view explaining steps to form a brass plated
layer of a ternary alloy;

FIG. 3C is a view explaining another steps to form a brass
plated layer of a ternary alloy; and
FIG. 4 is a conceptual view showing an adhesion reaction
layer formed at the interface between a rubber and a brass plated
layer.
Explanation of reference numerals
1: Pneumatic tire
9: Rubber-cord complex
10: Cord
12: Rubber
15: Element wire
15E: Element wire after drawing
16, 16E: Brass plated layer
17A, 17E: Plated wire
20A: Copper plated layer
20B: Zinc plated layer
25: Adhesion reaction layer
S: Interface of adhesion reaction layer
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of the present invention will be explained
below along with illustrated examples. FIG. 1 is a cross
sectional view showing a pneumatic tire in which a rubber-cord
complex of the present invention is used as a ply for tire
reinforcement. FIG. 2 is a cross sectional view showing the

above-mentioned ply which is the rubber-cord complex.
In FIG. 1, a pneumatic tire 1 shown in this example is
a radial tire for passenger cars, and it includes a carcass 6
extending from a tread portion 2 to bead cores 5 in bead portions
4 through sidewall portions 3, and a belt layer 7 arranged radially
outward of the carcass 6 in the tread portion 2.
In this example, the carcass 6 is formed of one or more
carcass plies 6A having carcass cords arranged, for example,
at an angle of 75 to 90 degrees with respect to the circumferential
direction of the tire. The carcass ply 6A comprises a ply main
body portion 6a extending between the bead cores 5, 5, and ply
turnup portions 6b that are turned up around the bead cores 5
from the inside to the outside at each end of the ply main body
portion 6a. A bead apex rubber 8 extending radially outwardly
from the bead core 5 in a tapered manner is disposed between
the ply main body portion 6 a and the ply turnup portion 6b, whereby
a portion from the bead portion 4 to the sidewall portion 3 is
reinforced.
The belt layer 7 comprises two or more belt plies, two
belt plies 7A, 7B in this example, having belt cords arranged
at an angle of 10 to 45 degrees with respect to the circumferential
direction of the tire. The belt plies are stacked so that the
belt cords in one ply intersects with those in another belt ply
to thereby enhance the belt rigidity so as to firmly reinforce
the tread portion 2.

In the present example, the rubber-cord complex 9 of the
present invention is adopted to the belt plies 7A, 7B out of
the plies for tire reinforcement including the carcass ply 6A
and the belt plies 7A, 7B.
As shown in FIG. 2, the rubber-cord complex 9 is composed
of a cord array body 11 that metal cords 10 as belt cords are
arranged mutually in parallel, and a rubber 12 for topping formed
by covering the surface and back of the cord array body 11 with
the rubber and subjecting the rubber to vulcanization-bonding
to the cord array body. The "vulcanization-bonding" is achieved
by vulcanization heat applied when an unvulcanized green tire
is vulcanized and molded in a mold.
As the rubber 12 for topping can be suitably used
conventional rubbers for use in tires, in which sulfur is
incorporated in a rubber base material. Besides sulfur, known
additives, e.g. , a vulcanization accelerator andavulcanization
acceleration assistant, are selectively used for the rubber 12
in order to obtain required physical properties of the rubber.
As the rubber base material are preferably used diene rubbers
such as natural rubber, isoprene rubber, butadiene rubber and
styrene/butadiene rubber. The diene rubbers are used alone or
in the form of a blend of two or more rubbers. Table 1 shows
an example of a rubber composition for the rubber 12. The
composition dose not contain any organocobalt salt as mentioned
above.


*1 2,2,4-trimethyl-l,2-dihydroquinoline polymer
*2 DZ: N,N'-dicyclohexyl-2-benzothiazolylsulfenamide
The metal cord 10 is composed of at least one drawn plated
wire 17E obtained by forming a brass plated layer 16 on the surface
of a metal element wire 15 and drawing the resulting plated wire .
In case that the metal cord 10 is composed of a plurality of
drawn plated wires 17E, the wires 17E are twisted in a known
twisting structure such as bundle-twisting or layer-twisting.
A metal cord 10 having a 1x3 structure where three plated wires
17E are twisted together is shown in FIG. 2.
The brass plated layer 16 is a brass-based plating
containing copper and zinc as main components. In the present
invention, it is possible to employ a binary alloy plating
comprised of copper and zinc, or a ternary alloy plating
containing, besides copper and zinc, cobalt or nickel as a third
metal. In both cases of the binary alloy plating and the ternary
alloy plating, it is preferable that the content of copper is
in the range of 60 to 80 parts by weight and the content of zinc
is in the range of 40 to 20 parts by weight, with respect to
100 parts by weight of the plating. Further, in the case of

the ternary alloy plating, it is preferable that the content
of cobalt is in the range of 0.1 to 5.0 parts by weight and the
content of nickel is in the range of 1.0 to 10.0 parts by weight.
As shown in FIG. 3 (A) , the brass plated layer 16 made of
the binary alloy plating is formed in such a manner that primary
plated layers 20, i.e., a copper plated layer 20A and a zinc
plated layer 2OB, are formed one after another on the surface
of a metal element wire 15 , and then sub j ected to thermal diffusion
to alloy the both metals (copper and zinc). Numeral 17A denotes
a plated element wire prior to drawing, and numeral 17E denotes
a plated wire after drawing. The copper plated layer 2 0A can
be formed by electroplating treatment in a copper plating bath
such as a copper pyrophosphate bath or a copper sulfate bath.
The zinc plated layer 20B can be formed by electroplating
treatment in a zinc plating bath such as a zinc sulfate bath.
Further, the thermal diffusion is performedby thermally treating
an element wire 15 having the copper plated layer 2 0A and the
zinc plated layer 20B in a heating apparatus.
In the case of forming the brass plated layer 16 made of
a ternary alloy plating, as shown in FIG. 3(B), in addition to
the copper plated layer 20A and the zinc plated layer 20B, a
third metal plated layer 20C is formed by electroplating
treatment in a third metal bath which is a cobalt bath or a nickel
bath, and the three layers are then thermally diffused and
alloyed.

The order of formation of respective primary plated layers
is not particularly restricted. However, in case that the
element wire 15 is made of steel, it is not preferable to firstly
form the zinc plated layer 2OB from the viewpoint of the plating
peeling property since a hard and fragile alloy phase of iron
and zinc is produced on the surface of the element wire 15.
Further, diffusion tends to occur with difficulty between the
copper plated layer 2 0A and the third metal plated layer 2 0C
as compared with an interface between other plated layers.
Therefore, it is preferable not to dispose the copper plated
layer 20A and the third metal plated layer 20C adjacently to
each other. Therefore, in the case of the binary alloy plating,
the order of the copper plated layer 2 0A and the zinc plated
layer 20B is preferred, and in the case of the ternary alloy
plating, the order of the copper plated layer 2OA, the zinc plated
layer 20B and the third metal plated layer 20C is preferred.
After formation of the brass plated layer 16, the plated
wire 17A is subjected to a known wire drawing process to give
a plated wire 17E drawn to a desired diameter. Numeral 16E
denotes a brass plated layer in the drawn plated wire 17E, and
numeral 15E denotes a wire 15 in the drawn plated wire 17E.
Further, another method for forming the brass plated layer
16 made of the ternary alloy plating is a method wherein, as
shown in FIG. 3 (C) , the copper plated layer 20A is firstly formed
on the surface of the metal wire 15 and, thereafter, a plated

layer 20D of an alloy of zinc and nickel or an alloy of zinc
and cobalt is formedonthe copperplated layer 20A. Subsequently,
the plated layers are subjected to thermal diffusion to give
the brass plated layer 16. This alloy plated layer 20D can be
formed by electroplating treatment in an alloy bath containing
zinc sulf ate and nickel or an alloy bath containing zinc sulf ate
and cobalt. When the brass plated layer 16 is formed in this
manner, the content of the third metal in the external surface
after the thermal diffusion decreases relatively as compared
with the case of forming the third metal plated layer 20C as
the outermost layer (the case shown in FIG. 3(B)). It is
therefore possible to improve the drawing processability in the
wire drawing step.
The adhesive property between the brass plated layer 16E
and the rubber 12 is exhibitedby formation of an adhesion reaction
layer 25 at an interface between the brass plated layer 16E and
the rubber 12, as shown in Fig. 4. The adhesion reaction layer
25 is formed from copper in the brass plated layer 16E and sulfur
incorporated in the rubber 12 that cause a cross-linking reaction
to combine each other during vulcanization of the rubber.
Improvement in wet heat adhesive property between the rubber
12 and the plated wire 17 canbeachievedby increasing the strength
of the adhesion reaction layer itself and increasing the adhesive
force between the adhesion reaction layer 25 and the rubber 12.
For this purpose, in the present invention, when the metal

cord 10 to which the same rubber as the above-mentioned rubber
12 has been vulcanized and bonded, or the rubber-cord complex
9 itself, is in the wet heat deterioration state after being
held in an atmosphere at a temperature of 50 to 100°C and a relative
humidity of 60 to 100% for one hour to 20 days, the adhesion
reaction layer 25 is required to have an average thickness Tn
of 50 to 1,000 nm, and the interface S between the adhesion reaction
layer 25 and the rubber 12 is required to have a fractal dimension
of 1.001 to 1.300. In addition, in order to further ensure the
effects of improvement in wet heat adhesive property, the wet
heat deterioration environment is preferably set at a temperature
of 70 to 100°C and a relative humidity of 80 to 100% for a period
of 10 to 20 days.
If the average thickness Tn of the adhesion reaction layer
25 is less than 50 nm, the adhesion reaction layer 25 is so thin
that the adhesive strength is insufficient. On the other hand,
if the average thickness Tn exceeds 1, 0 00 nm, the cross-linking
density of the adhesion reaction layer 25 decreases to result
in reduction of adhesive strength. It is therefore preferable
that the average thickness Tn of the adhesion reaction layer
25 is 100 nm or more, and is 500 nm or less.
As well known, the "fractal dimension" is an index for
showing a complexity of a shape, a degree of irregularity of
a surface, and the like. The larger the fractal dimension value,
the more complex the irregularity is. In the present embodiment,

the fractal dimension of the interface S of the adhesion reaction
layer 25 is set to 1.001 or more, thereby increasing the degree
of irregularity of the interface S to render it complicated and
increasing the surface area thereof. It is thereby possible
to enhance the bonding force between the adhesion reaction layer
25 and the rubber 12. If the fractal dimension is less than
1.001, the bonding force between the adhesion reaction layer
25 and the rubber 12 after the wet heat deterioration is decreased.
However, if the degree of irregularity becomes large to such
an extent that the fractal dimension exceeds 1.3 00, the bonding
force between the adhesion reaction layer 25 and the rubber 12
after the wet heat deterioration decreases. Therefore, it is
preferable that the lower limit of the fractal dimension is at
least 1.050, especially at least 1.100, and the upper limit of
the fractal dimension is at most 1.250.
Further, as well known, the "fractal dimension" can be
obtained, for example, by a box counting method. Specifically,
for example, a TEM photograph (transmission electron microscopic
photograph) of an adhesion reaction layer is subjected to image
processing to extract a curved line along its interface. The
fractal dimension of the extracted curved line is then obtained
by the box counting method. In this box counting method, the
curved line is divided into small square regions (boxes) each
having one side with a length of "r" , and while the length "r"
is changed, the number of small regions (boxes) each including

a segment of the target curved line is counted. The counted
number of small regions (boxes) is plotted as ordinate and the
length of "r" at the time of counting is plotted as abscissa
on a logarithmic graph, and the fractal dimension is obtained
from the inclination of the graph. The average thickness Tn
of the adhesion reaction layer 25 can also be obtained from the
above-mentioned curved line along the interface shape.
The fractal dimension of the interface S of the adhesion
reaction layer 2 5 and the average thickness Tn of the adhesion
reaction layer 25 can be adjusted by selecting the conditions
of the current density and the diffusion temperature in
electroplating for the copper plating and the zinc plating, and
also by selecting the current density condition in plating of
the third component.
Preferable conditions on the fractal dimension of the
interface S of the adhesion reaction layer 25 and the average
thickness Tn of the adhesion reaction layer 25 are as mentioned
below, namely
(A) to set the current density of electroplating within a specif ic
range higher than a conventional one, in formation of the primary
plated layers 20 (20A, 20B, 20C); and
(B) to set the temperature (diffusion temperature) in thermal
diffusion treatment within a specific range lower than a
conventional one;
whereby the adhesion reaction layer 25 as defined above can be

obtained. Specifically, it is preferable that the current
density in electroplating for the copper plated layer 2 0A is
raised to the range of 15 to 25 A/dm2, the current density in
electroplating for the zinc plated layer 20B is raised to the
range of 40 to 60 A/dm2, and the thermal diffusion is performed
at a low diffusion temperature within the range of 500 to 550°C.
It should be noted that in a conventional brass plating of wires,
the current density for the copper plated layer is set to about
10A/dm2, the current density for the zinc plated layer is set
to about 20A/dm2, and the diffusion temperature is set to a range
of 560 to 600°C. Further, in the case of conducting
electroplating for the third metal plated layer 20C, it is
preferable to raise the current density to the range of 3 0 to
4 0 A/dm2.
Further, as shown in FIG. 3(C), in the case of forming
a zinc alloy plated layer 20D, i.e., zinc/nickel alloy plated
layer or zinc/cobalt alloy plated layer in place of the zinc
plated layer 20B, the current density in electroplating for the
zinc alloy plated.layer 20D is set to the range of 40 to 60 A/dm2,
as in the case of the zinc plated layer 20B.
As stated above, the brass plated layer 16E may be a ternary
alloy plating containing nickel or cobalt. However, in the case
of adding nickel as a third metal, if the amount of nickel added
is less than 1.0 part by weight based on 100 parts by weight
of the plating, the plated layer 16E is easy to change to a fragile

grain structure after wet heat deterioration and tends to cause
peeling from this changed portion. On the other hand, if the
amount of nickel added exceeds 10.0 parts by weight, the thickness
T of the adhesion reaction layer 25 becomes thin to decrease
the adhesive strength, and also the plated layer 16E becomes
hard to deteriorate the wire drawing processability. Hence,
the amount of nickel added is preferably within the range of
1.0 to 10.0 parts by weight.
Further, in the case of adding cobalt as a third metal,
if the amount of cobalt added is less than 0.1 part by weight
based on 10 0 parts by weight of the plating, the plated layer
16 is easy to change to a fragile grain structure after wet heat
deterioration and tends to cause peeling from this changed
portion. On the other hand, if the amount of cobalt added exceeds
5.0 parts by weight, the thickness T of the adhesion reaction
layer 25 becomes thin to decrease the adhesive strength, and
also the plated layer 16E becomes hard to deteriorate the wire
drawing processability. Hence, the amount of cobalt added is
preferably within the range of 0.1 to 5.0 parts by weight.
In the present example has been illustrated a case where
the rubber-cord complex 9 is applied to a ply for tire
reinforcement, particularly a belt ply. However, the
rubber-cord complex 9 can also be applied to other plies for
tire reinforcement, such as a carcass ply and a bead reinforcing
ply. Further, the metal cord 10 may be used as a bead wire for

forming a bead core 5. In such a case, the metal cord 10 is
made of a single plated wire 17, and it is considered that the
pneumatic tire 1 itself constitutes the rubber-cord complex 9.
In addition to those described above, the rubber-cord complex
9 is also applicable to a variety of rubber products such as
a hose and a industrial belt. Further, as the material for the
metal element wire 15 can be used, besides steel mentioned above,
a variety of metal materials which are capable of forming the
brass plated layer 16, such as aluminum, copper and titanium,
and with the use of any of the metal materials, it is possible
to effectively exert the above-mentioned action and effect.
A particularly preferable embodiment of the present
invention has been described above in detail, but the present
invention is not limited to the embodiment shown in the drawings
and various changes and modifications can be made in practicing
the invention.
Examples
(1) A brass plated layer was formed on the surface of a
steel wire having a diameter of 1.7 mm. The plated wire was
then subjected to wire drawing treatment to give a drawn plated
wire having a diameter of 0.27 mm.
The brass plating was carried out by any of the following
methods.
(A) A copper plated layer and a zinc plated layer were

successively formed and then subjected to a thermal diffusion
treatment to form a binary alloy brass plated layer. This method
is referred to as a method A.
(B) A copper plated layer, a zinc plated layer and a third
metal plated layer were successively formed and then subjected
to a thermal diffusion treatment to form a ternary alloy plated
layer. This method is referred to as a method B.
(C) A copper plated layer and a zinc alloy (zinc/nickel
alloy or zinc/cobalt alloy) plated layer were successively formed
and then subjected to a thermal diffusion treatment to form a
ternary alloy plated layer. This method is referred to as a
method C.
Both sides of an array of metal cords each of which is
formed by twisting the drawn plated wires and has a 1x3 structure,
were sandwiched between unvulcanized rubber sheets having the
composition shown in Table 1, and then heated in a press-contacted
state (165°C, 18 minutes) for vulcanization to give a sample
of a cord ply. Each of the samples obtained in such a manner
was then subjected to a peeling test, and the initial adhesive
property and the wet heat adhesive property of the metal cords
were compared.
The wet heat adhesive property was measured by allowing
the above-mentioned sample to stand in an oven at a temperature
of 80°C and a relative humidity of 95% for 20 days and then
subjecting the sample in a wet heat deterioration state to a

peeling test. The initial adhesive property was measured by-
allowing the sample after the vulcanization to natural cooling
at ordinary temperature and humidity [20°C, 50%(relative
humidity)] and then subjecting it to a peel ing test. The peeling
test was conducted by peeling the sample from its one end along
the rubber/metal cord interface at a speed of 50 mm/min., and
the state of the metal cord surface at the interface was evaluated
according to the following criteria.
5: The surface is fully covered with the rubber, and the plated
layer surface of the steel cord is invisible.
4 : The plated layer is visible at 3 to 6 places on the peeled
surface.
3 : The plated layer is visible at 11 to 16 places on the peeled
surface.
2 : The plated layer is visible at 21 or more places on the peeled
surface, but not less than 6 0% of the whole plated layer surf ace
is covered with the rubber.
1: The total area of the plated layer surface covered with the
rubber is not less than 10% and less then 30%.
In Table 2, the evaluation is performed with scores in
steps of 0.5, where a surface state out of the integer score
range applies such evaluation.
(2) A pneumatic tire (size: 195/65R15) using the
above-mentioned steel cord as a belt cord was produced according
to the following specification, and the high-speed durability

of the tire was tested.
(Belt layer)
The number of plies: 2 plies
Cord angle: (+20°, -20°)
The number of cords: 40 cords/5 cm
(Carcass)
Cord: 1,670 dtex/2 (polyester)
The number of plies: 1 ply
Cord angle: (90°)
The number of cords: 50 cords/5 cm

Under conditions of an internal pressure of 28 0 kPa and
a load of 492 kgf, a drum driving test apparatus was started
at a speed of 170 km/h, and the speed was increased in stages
by 10 km/h every 10 minutes. A distance driven until destruction
of the tire was measured and shown as an index relative to the
result of Comparative Example 1 taken as 100. The larger the
value, the better the high-speed durability is.





As shown in the table, it can be confirmed from the peeling
test that the metal cords of the examples according to the present
invention are excellent in adhesive property after wet heat
deterioration to the rubber. Further, it can also be confirmed
from the high-speed durability test that reduction in adhesive
property due to heat can be suppressed to thereby allow
improvement in high-speed durability of tires.
WHAT IS CLAIMED IS:
1. A rubber-cord complex obtained by vulcanizing a rubber
to adhere it to a metal cord comprising a drawn plated wire prepared
by providing a plated layer of brass containing copper and zinc
on the surface of a metal wire and drawing the resulting plated
wire, wherein:
the rubber-cord complex has an adhesion reaction layer
formed by a cross-linking reaction of sulfur in the rubber and
copper in the brass plated layer, between the rubber and the
brass plated layer, and
in the wet heat deterioration state of the metal cord to
which the rubber has been vulcanized and bonded and which has
been held in an atmosphere having a temperature of 50 to 10 0°C
and a humidity of 60 to 10 0% for one hour to 20 days, the average
thickness of the adhesion reaction layer is from 50 to 1,000
nm , and the interface between the adhesion reaction layer and

the rubber has a fractal dimension of 1.001 to 1.300.
2. The rubber-cord complex of claim 1, wherein the brass
plated layer contains 0.1 to 5.0 parts by weight of cobalt or
1. 0 to 10. 0 parts by weight of nickel based on 100 parts by weight
of the plating.
3. The rubber-cord complex of claim 1 or 2, wherein the
brass plated layer is formed by thermal diffusion of a copper
plated layer and a zinc plated layer formed in layers on the
metal wire, in which the copper plated layer is formed by plating
at a current density of 15 to 25 A/dm2, the zinc plated layer
is formed by plating at a current density of 40 to 60 A/dm2,
and the thermal diffusion is conducted by a low temperature
diffusion at a temperature of 500 to 550°C.
4. The rubber-cord complex of any one of claims 1 to 3,
wherein the metal cord comprises at least one said drawn plated
wire.
5. Ametal cord for use in the rubber-cord complex according
to claims 1 to 3, wherein the brass plated layer is formed by
thermal diffusion of a copper plated layer and a zinc plated
layer formed by plating in layers on the metal wire, in which
the copper plated layer is formed by plating at a current density

of 15 to 25 A/dm2, the zinc plated layer is formed by plating
at a current density of 40 to 60 A/dm2, and the thermal diffusion
is conducted by a low temperature diffusion at a temperature
of 500 to 550°C.
6. Ametal cord for use in the rubber-cord complex according
to claims 1 to 3, wherein the brass plated layer is formed by
thermal diffusion of a copper plated layer and a plated layer
of a zinc alloy selected froma zinc-nickel alloy anda zinc-cobalt
alloy, the layers being formed in layers on the metal wire, in
which the copper plated layer is formed by plating at a current
density of 15 to 25 A/dm2, the zinc alloy plated layer is formed
by plating at a current density of 40 to 60 A/dm2, and the thermal
diffusion is conducted by a low temperature diffusion at a
temperature of 500 to 55 0°C.
7. A pneumatic tire in which the rubber-cord complex
according to claims 1 to 4 is used as a ply for tire reinforcement.

A rubber-cord complex 9 having an improved wet heat
adhesive property between a rubber and a cord comprising a drawn
plated wire, and including a cord 10 comprising a drawn plated
wire 17 prepared by providing a brass plated layer 16E on the
surface of an element wire 15 and drawing the resulting plated
wire, and a rubber 12 vulcanized and bonded to the cord 10, wherein
the rubber-cord complex 9 has an adhesion reaction layer 25 formed
by a cross-linking reaction of sulfur and copper, between the
rubber 12 and the brass plated layer 16E, and in a wet heat
deterioration state after being subjected to the vulcanization
to bond the rubber 12 thereto and further held under an atmosphere
having a temperature of 50 to 100°C and a humidity of 60 to 100%
for one hour to 20 days, the adhesion reaction layer 25 has an
average thickness of 50 to 1, 000 nm, and the interface S between
the adhesion reaction layer 25 and the rubber has a fractal
dimension of 1.001 to 1.300.

Documents:

02001-kolnp-2008-abstract.pdf

02001-kolnp-2008-claims.pdf

02001-kolnp-2008-correspondence others.pdf

02001-kolnp-2008-description complete.pdf

02001-kolnp-2008-drawings.pdf

02001-kolnp-2008-form 1.pdf

02001-kolnp-2008-form 3.pdf

02001-kolnp-2008-form 5.pdf

02001-kolnp-2008-international publication.pdf

02001-kolnp-2008-international search report.pdf

02001-kolnp-2008-pct priority document notification.pdf

02001-kolnp-2008-pct request form.pdf

2001-KOLNP-2008-(01-11-2013)-ABSTRACT.pdf

2001-KOLNP-2008-(01-11-2013)-ANNEXURE TO FORM 3.pdf

2001-KOLNP-2008-(01-11-2013)-CLAIMS.pdf

2001-KOLNP-2008-(01-11-2013)-CORRESPONDENCE.pdf

2001-KOLNP-2008-(01-11-2013)-DESCRIPTION (COMPLETE).pdf

2001-KOLNP-2008-(01-11-2013)-DRAWINGS.pdf

2001-KOLNP-2008-(01-11-2013)-FORM-2.pdf

2001-KOLNP-2008-(01-11-2013)-GPA.pdf

2001-KOLNP-2008-(01-11-2013)-OTHERS.pdf

2001-KOLNP-2008-(01-11-2013)-PETITION UNDER RULE 137.pdf

2001-KOLNP-2008-(06-08-2013)-ANNEXURE TO FORM 3.pdf

2001-KOLNP-2008-(06-08-2013)-CORRESPONDENCE.pdf

2001-KOLNP-2008-(06-08-2013)-OTHERS.pdf

2001-KOLNP-2008-(19-03-2013)-CORRESPONDENCE.pdf

2001-KOLNP-2008-ASSIGNMENT.pdf

2001-KOLNP-2008-CLAIMS 1.1.pdf

2001-KOLNP-2008-CORRESPONDENCE 1.1.pdf

2001-KOLNP-2008-CORRESPONDENCE.pdf

2001-KOLNP-2008-FORM 13.pdf

2001-KOLNP-2008-FORM 18.pdf

2001-KOLNP-2008-FORM 3.1.pdf

2001-KOLNP-2008-PA.pdf

abstract-2001-kolnp-2008.jpg


Patent Number 265124
Indian Patent Application Number 2001/KOLNP/2008
PG Journal Number 07/2015
Publication Date 13-Feb-2015
Grant Date 09-Feb-2015
Date of Filing 19-May-2008
Name of Patentee NIPPON STEEL CORPORATION
Applicant Address 6-3, OTEMACHI 2-CHOME CHIYODA-KU, TOKYO
Inventors:
# Inventor's Name Inventor's Address
1 MIYAZAKI SHINICHI 9, WAKINOHAMA-CHO 3-CHOME, CHUO-KU, KOBE-SHI, HYOGO-KEN
2 SAKAI YASUO C/O SUMITOMO ELECTRIC TOCHIGI CO., LTD. 18-4, KIYOHARA-KOGYODANCHI, UTSUNOMIYA-SHI, TOCHIGI-KEN
3 ARAMAKI KEISUKE BLOSSOM B-201, 69-32 TAKARAGI CHO 1-CHOME, UTSUNOMIYA-SHI, TOCHIGI-KEN
4 OKAMOTO KENICHI C/O SUMITOMO (SEI) STEEL WIRE CORP. 1-1, KOYAKITA 1-CHOME, ITAMI-SHI, HYOGO-KEN
5 SANO YUICHI C/O SUMITOMO ELECTRIC TOCHIGI CO., LTD. 18-4, KIYOHARA-KOGYODANCHI, UTSUNOMIYA-SHI, TOCHIGI-KEN
6 KODAMA JUNICHI C/O NIPPON STEEL CORPORATION SHINTOMI 20-1, FUTTSU-SHI, CHIBA-KEN
PCT International Classification Number D07B 1/06,B60C 9/00
PCT International Application Number PCT/JP2006/323964
PCT International Filing date 2006-11-30
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 2005-359332 2005-12-13 Japan