Title of Invention	"A PROCESS FOR PRODUCING A SEALANT-CONTAINED TIRE-TUBE"
Abstract	[PURPOSE]  The purpose of the present invention is to efficiently produce a sealant-contained tire tube having an air chamber filled with air and a sealant chamber filled with a sealant. [ARRANGEMENT] A tube blank 2" whose inside is divided into an air chamber 3 and a sealant chamber 7 by a partition wall 5, is formed by extrusion and cut into a predetermined length. An air valve 6 3 is mounted to the tube blank 2" to communicate with the air chamber 3 and then/ opposite ends of the tube blank 2" is bonded by pressure bonding and vulcanized. A sealant charging bore 4i is formed in the tube blank 2" to communicate with the sealant chamber 7. Thereafter; air is supplied to the air chamber 3 through an air valve 6 3 to urge the partition wall 5, thereby expelling the air from the sealant chamber 7. In this state, a sealant 8 is supplied into the sealant chamber 7 through the sealant charging bore 4:. The sealant charging bore 4: is closed by affixing a raw rubber sheet 19 and vulcanizing it. [DRAWING TO BE SELECTED] Fig.2

Title of Invention

"A PROCESS FOR PRODUCING A SEALANT-CONTAINED TIRE-TUBE"

Abstract

[PURPOSE]  The purpose of the present invention is to efficiently produce a sealant-contained tire tube having an air chamber filled with air and a sealant chamber filled with a sealant. [ARRANGEMENT] A tube blank 2" whose inside is divided into an air chamber 3 and a sealant chamber 7 by a partition wall 5, is formed by extrusion and cut into a predetermined length. An air valve 6 3 is mounted to the tube blank 2" to communicate with the air chamber 3 and then/ opposite ends of the tube blank 2" is bonded by pressure bonding and vulcanized. A sealant charging bore 4i is formed in the tube blank 2" to communicate with the sealant chamber 7. Thereafter; air is supplied to the air chamber 3 through an air valve 6 3 to urge the partition wall 5, thereby expelling the air from the sealant chamber 7. In this state, a sealant 8 is supplied into the sealant chamber 7 through the sealant charging bore 4:. The sealant charging bore 4: is closed by affixing a raw rubber sheet 19 and vulcanizing it. [DRAWING TO BE SELECTED] Fig.2

Full Text	[DETAILED DESCRIPTION OF THE INVENTION] [Field of Industrial Application] The present invention relates to a process for producing a tire tube having a sealant contained therein and including an air chamber filled with air and a sealant chamber filled with a sealant. [Prior Art] In a usual tube-incorporated tire/ if a tube gets a punctured wound caused by a nail or the like, air in the tube is leaked from the punctured wound through a small clearance between the tire and the tube and via.a. nipple bore in the rim to the outside and, the tire becomes flat. Therefore, there is a conventionally known a tube-incorporated tire including a liquid sealant- which is previously injected in an appropriate amount for automatic emergence repairing of a puncture when the tube is punctured (see Japanese Patent Application Laid-open No.58-74342). [Problems to be solved by the Invention] In the above known tire, however, a capsule filled with the sealant is incorporated into the tube in forming the tube, and after the formation, the capsule is broken to charge the sealant into the tube. For this reason, when an external force is applied to break the capsule, not only the tube is prone to be damaged, but also the sealant may clog an air valve of the tube, and may clog a pressure gauge when an air pressure within the tube is measured. To solve this problem, the inside of the tube may be divided into an air chamber filled with air, and a sealant chamber filled with the sealant, and the sealant may be charged directly into the sealant chamber without use of a capsule. Accordingly, it is an object of the present invention to provide a process for efficiently producing a sealant-contained tire tube including an air chamber and a sealant chamber. [Approach to solve the Problems] To achieve the above object, according to claim 1 of the present invention, there is provided a process for producing a sealant-contained tire tube including an air chamber filled with air and a sealant chamber filled with a sealant, step for process comprising: a first step for extruding a tube blank including a peripheral wall of a circular section in which an air chamber and a sealant chamber are defined by a partition wall; a second step for bonding step for tube blank at its opposite ends into an annular shape; a third step for forming a sealant charging bore in step for peripheral wall to communicate with step for sealant chamber; a fourth step for charging the sealant into step for sealant chamber through step for sealant charging bore in a state in which air has been charged into step for air chamber; and a fifth step for closing step for sealant charging bore formed in step for peripheral wall. According to claim 2, in addition to claim 1, the air is charged into the air chamber through an air valve mounted in the peripheral wall at the fourth step. According to claim 3, in addition to claim 1, a raw rubber sheet is affixed to the sealant charging bore and vulcanized to close the sealant charging bore. According the invention as defined in claim 4, there is provided a process for producing a sealant-contained tire tube including an air chamber filled with air and defined between a partition wall and an air chamber peripheral wall constituting a half periphery of a peripheral wall having a circular section by partitioning the inside of the peripheral wall, and a sealant chamber filled with a sealant and defined between the partition wall and a sealant chamber peripheral wall constituting a remaining half peripheral of the peripheral wall, the process comprising: a first step of forming a tube blank by extrusion, such that a free length of the partition wall is substantially equal to a free length of the air chamber peripheral wall and a free length of the sealant chamber peripheral wall; a second step of cutting the tube blank into a predetermined length; a third step of compressing opposite ends of the tube blank in a diametrical direction to superpose the air chamber peripheral wall, the partition wall and the sealant chamber peripheral wall into three layers; and a fourth step of bringing the compressed opposite ends of the tube blank into pressure contact with each other to bond t;hem/ According to the invention as defined in claim 5, in addition to claim 4, the tube blank is formed by extrusion at the first step, such that the section of the partition wall is corrugated. [BRIEF DESCRIPTION OF THE DRAWINGS] [Fig.l] A cross-sectional view of a wheel on which a tube-incorporated tire is mounted [Fig.2] A view showing tube-producing steps [Fig.3j A cross-sectional view of a tube blank [Fig.4) A partial sectional view of an extruder [Fig.5] An enlarged view taker, along the arrow 5 [Fig.6] A side view of a splicer [Fig.7] An enlarged view taken along the line 7-7 in Fig.6 [Fig.8] A sectional view of a heating die. [Fig.9) A view showing another embodiment of th« tube blank [Embodiment] The present invention will now be described by way of a preferred embodiment with reference to the accompanying drawings. Figs.l to 8 show a first embodiment of the present invention, wherein: Fig.l is a cross-sectional view of a wheel on which a tube-incorporated tire is mounted; Fig.2 shows tube-producing steps; Fig.3 is a cross-sectional view of a tube blank; Fig.4 is a partial sectional view of an extruder; Fig.5 is an enlarged view taken along the arrow 5; Fig.6 is a side view of a splicer; Fig.7 is an enlarged view taken along the line 7-7 in Fig.6; and Fig.8 is a sectional view of a heating die. Referring to Fig.l, a rim R of a wheel for a motorcycle is connected to a hub (not shown) through a wire spoke. A tube-incorporated tire T including a tire 1 and a rube 2 contained in the tire 1 is mounted on the rim R. The tube 2 includes a peripheral wall 4 which is formed to have an annular section and which includes an air chamber peripheral wall portion 4i located at a radially inner side and a sealant chamber peripheral wall portion 4o located at a radially outer side. A pair of connections connecting the air chamber peripheral wail portion 4i and the sealant chamber peripheral wall portion 4o of the peripheral wall 4 are connected to each other by a partition wall 5 which is formed integrally with the connections. Air is filled in an air chamber 3 which is substantially circular in section and which is defined between the air chamber peripheral wall portion 4i and the partition wall 5. A known liquid sealant 8 is filled in a sealant chamber 7 which is substantially arcuate in section which is defined between the sealant chamber peripheral wall portion 4o and the partition wall 5. The air chamber peripheral wall portion 4i is provided with an air valve 6 for charging air into the air chamber 3. The sealant chamber 7 in the tube 2 is maintained in a shape extending along an inner surface -of the tire 1 by an air pressure in the air chamber 3. Hence, even if a centrifugal force is applied to the sealant filled in the sealant chamber 7 during rotation of the wheel, the sealant 8 can be prevented from being offset toward an outer periphery of the tube 2. Therefore, even if the tube gets a punctured wound radially or sideways by a nail or the like, the sealant 8 immediately fills the punctured wound to repair the tube 2, thereby retarding the leakage of air from the air chamber 3. The sealant 8 is retained in the sealant chamber 7 and cannot flow into the air chamber 3 and hence, the sealant 8 cannot clog the air valve 6, a pressure gauge mounted to the air valve and the like. A process for producing the rube 2 will be described below. As shown in Fig.2, the process for producing the cube 2 includes a material kneading step, a tube blank extruding step, a cutting step, an air valve mounting step, a bonding step, a first vulcanizing step, a boring step, a sealant charging step, a raw rubber sheet affixing step, a second vulcanizing step and an inspecting step. First, a material resulting from the kneading at the material kneading step is subjected to an extrusion at the tube blank extruding step, thereby forming a tube blank 2' made of a raw rubber. As shown in Figs. 3 to 5, the tube blank 2' continuously extruded from a nozzle 12 of an extruder II includes a peripheral wall circular in cross section, and a partition wall 5 connecting two points of the peripheral wall 4 located on a diametrical line, in a wave-like shape. In other words, the peripheral wall 4 is divided, at a boundary provided by the connection between the peripheral wall 4 and the partition wall 5, into an air chamber peripheral wall portion 4i and a sealant chamber peripheral wall portion 4o. The length Li of the air chamber peripheral wall portion 4i, the length Lo of the sealant chamber peripheral wall portion 4o and the length Lc of the partition wall 5 are set at substantially equal values. By forming the partition wall 5 into a wave-like shape, the above length Lc can be insured without creation of a steep bent portion. The nozzle 12 of the extruder 11 for extruding the tube blank 2' has two mold release agent discharge ports 13 and two mold release agent intake ports 14 provided therein for discharging and supplying a mold release agent such as talc from and to the air chamber 3 and the sealant chamber 7. By forming the air chamber 3 and the sealant chamber 7 into the same sectional area by the partition wall 5 having the wave-like cross section, a space for disposition of the mold release agent discharge ports 13 and the mold release agent intake ports 14 can be easily insured. At the subsequent cutting step, the tube blank 2' is cut into a predetermined length and then, at the air valve mounting step, the air valve 6 is mounted at place to the air chamber peripheral wall 4i. Further, at bonding step, the opposite ends of the tube blank 2' are bonded. ' ' Figs. 6 and 7 show a splicer used at the bonding step. The opposite ends of the tube blank 2' are clamped by a cramp 17 comprised of a pair of cramp members 15 and 16, such that the opposite ends of the tube blank 2' slightly protruding from the clamp members 15 and 16 are pressure-bonded to each other. The tube blank 2' made of the raw rubber before being vulcanized is bonded into an annular shape by the pressure bonding. At this time, in order to correctly bond the air chamber peripheral wall portion 4i, the partition wall 5 and the sealant chamber peripheral wall portion 4o at one end of the tube blank 2' to the air chamber peripheral wall portion 4i, the partition wall 5 and the sealant chamber peripheral wall portion 4o at the other end of the tube blank 2', the partition wall 5 is sandwiched between the air chamber peripheral wall portion 4i and the sealant chamber peripheral wall portion 4o and clamped by the cramp 17 to form three layers (see Fig.7) . Because all of the length Li of the air chamber peripheral wall portion 4i, the length Lc of the partition wall 5 and the length Lo of the sealant chamber peripheral wall portion 4o are set equally (see Fig.3), as described above, the air chamber peripheral wall portion 4i, the partition wall 5 and the sealant chamber peripheral wall portion 4o are clamped as being of natural lengths, without being compressed or expanded. Thus, the air chamber peripheral wall portion 4i, the partition wall 5 and the sealant chamber peripheral wall portion 4o are prevented from being wrinkled, and can be reliably bonded together. At the next first vulcanizing step, as shown in Fig.8, the tube blank 2' is placed into a heating die 18, and the air chamber peripheral wall portion 4i and the sealant chamber peripheral wall portion 4o are brought into close contact with the heating die 18 and at the same time, the partition wall 5 is brought into close contact with the sealant chamber peripheral wall portion 4o by supplying heated air and hot steam into the air chamber 3 through the air valve 6. In this state, the heating die 18 is heated to conduct the vulcanization. At the subsequent boring step, the sealant chamber peripheral wall portion 4o of the tube blank 2' with a selant charging bore 4: and then, at the sealant charging step, the sealant 8 is charged through the sealant charging bore 4i into the sealant chamber 7. In this case, air is supplied through the air valve 6 into the air chamber 3 to expand the air chamber 3 prior to the charging of the sealant 8, thereby causing the partition wall 5 to be brought into close contact with the sealant peripheral wall portion 4o as in the state shown in Fig. 8 to completely discharge the air within the sealant chamber. In this state, the charging of the sealant 8 is started. In this manner, by starting the charging of the sealant 8 in the state in which the air in the sealant chamber 7 has been completely discharged, the incorporation of the air into the sealant 8 can be reliably prevented, and only the sealant 8 can be charged. In addition, since the air is supplied into the air chamber 3 by utilizing the air valve 6, it is unnecessary to open a bore used for charging the air. Then, at the raw rubber sheet affixing step, a raw rubber sheet 19 is affixed to cover the sealant charging bore 4: and then, a portion of the tube blank 2' in the vicinity of the raw rubber sheet 19 is locally vulcanized at the second vulcanizing step to close the sealant charging bore 4:, thereby finishing a tube 2. Because the sealant charging bore 4: is closed using the raw rubber sheet 19 which is the same material as for the tube blank 2' , the strength of the closed portion can be enhanced to reliably prevent the leakage of the sealant 8. The finished tube 2 is then inspected at the inspecting step to complete the producing process. Although the embodiment of the present invention has been described in'detail, it will be understood that the present invention is not limited to the above-described embodiment, and various modifications may be made without departing from the subject matter and scope of the invention defined claims. For example, the shape of the partition wall 5 in forming the tube blank 2' by extrusion is not limited to the wave-like shape in the embodiment and may be another wave-like shape as shown in Fig.9. [Effect of the Invention] According to the invention as defined in claim 1, as described above, the tube blank including the air chamber and the sealant chamber defined by dividing the inside of the peripheral wall having the circular section is formed by extrusion, and the sealant is charged into the sealant chamber. Thereafter, the sealant.charging bore is closed. Therefore, the air chamber and the sealant chamber can be reliably separated from each other, while preventing a damage of the tube, and the sealant can be prevented from clogging an air valve and from being leaked. In addition, since the sealant is charged into the sealant chamber through the sealant charging bore in the state in which the air has been charged into the air chamber, the air can be expelled from the sealant chamber prior to the charging of the sealant to avoid the mixing of the sealant with the air. According to the invention as defined in claim 2, because the air is charged into the air chamber through an air valve mounted in the peripheral wall at the fourth step, the need for provision of a special air-charging bore in the peripheral wall can be eliminated, leading to a reduced number of fabricating steps. According to the invention as defined in claim 3, because a raw rubber sheet is affixed to the sealant charging bore and vulcanized to close the sealant charging bore, the sealant charging bore can be reliably closed to prevent the leakage of the sealant. According to the invention as defined in claim 4, the air camber and the sealant chamber can reliably separated from each other to prevent the leakage of the sealant by the fact that the air chamber filled with air is defined between the air chamber peripheral wall constituting the half periphery of the peripheral wall and the partition wall, and the sealant chamber filled with the sealant is defined between the sealant chamber peripheral wall constituting the remaining half periphery of the peripheral wall and the partition wall. In addition, the tube blank is formed by extrusion, such that the free length of the partition wall is substantially equal to the free length of the air chamber peripheral wall and the free length of the sealant chamber peripheral wall, and therefore, in compressing the opposite ends of the tube blank cut into the predetermined length in the diametrical direction to superpose the air chamber peripheral wall, the partition wall and the sealant chamber peripheral wall into the three layers, the air chamber peripheral wall, the partition wall and the sealant chamber peripheral wall can be prevented from being wrinkled, thereby reliably performing the bonding. According to the invention as defined in claim 5, the tube blank is formed by extrusion, such that the section of the partition wall is corrugated. Therefore, it is possible of insure a required length of the partition wall, while preventing a sharp bending of the partition wall. (Explanation of Reference Numerals] 2' tube blank 3 air chamber 4 peripheral wall 4: sealant 41 peripheral wall of air chamber 4o peripheral wall of sealant chamber 5 partition wall 6 air valve 7 sealant chamber 8 sealant 19 raw rubber sheet [ciaim l] A process for producing a sealant-contained tire tube including an air chamber (3) filled with air and a sealant chamber (7) filled with a sealant (8), said process comprising: a first step for extruding a tube blank (21) including a peripheral wall (4) of a circular section in which an air chamber (3) and a sealant chamber (1) are defined by a partition wall (5); a second step for bonding said tube blank (21) at its opposite ends into an annular shape; a third step for forming a sealant charging bore (4-J in said peripheral wall to communicate with said sealant chamber (7); a fourth step for charging the sealant (8)' into said sealant chamber (7) through said sealant charging bore (4;) in a state in which air has been charged into said air chamber (3) ; and a fifth step for closing said sealant charging bore (4-J formed in said peripheral wall. [Claim 2] A process for producing a sealant-contained tire tube according to claim 1, wherein the air is charged, at said fourth step, into said air chamber (3) through an air valve (6) mounted in said peripheral wall (4). [Claim 3] A process for producing a sealant-contained tire tube according to claim 1, wherein a raw rubber sheet (19) is affixed to said sealant charging bore (4;) and vulcanized to close said sealant charging bore (4i). [Claim 4] A process for producing a sealant-contained tire tube including an air chamber filled with air and defined between a partition wall and an air chamber peripheral wall constituting a half periphery of a peripheral wall having a circular section by partitioning the inside of the peripheral wall, and a sealant chamber filled with a sealant and defined between the partition wall and a sealant chamber peripheral wall constituting a remaining half peripheral of the peripheral wall/ said process comprising: a first step of forming a tube blank by extrusion/ such that a free length of the partition wall is substantially equal to a free length of the air chamber peripheral wall and a free length of the sealant chamber peripheral wall; a second step of cutting the tube blank into a predetermined length; a third step of compressing opposite ends of the tube blank in a diametrical direction to superpose the air chamber peripheral wall/ the partition wall and the sealant chamber peripheral wall into three layers; and a fourth step of bringing the compressed opposite ends of the tube blank into pressure- contact with each other to bond them. [Claim 5] A process for producing a sealant-contained tire tube according to claim 4, wherein said tube blank is formed by extrusion at said first step, such that the section of the partition wall is corrugated. 6. A process for producing a sealant-contained tire tube substantially as hereinbefore described with reference to and as illustrated in the accompanying drawings.

Full Text

[DETAILED DESCRIPTION OF THE INVENTION] [Field of Industrial Application]
The present invention relates to a process for producing a tire tube having a sealant contained therein and including an air chamber filled with air and a sealant chamber filled with a sealant.
[Prior Art]
In a usual tube-incorporated tire/ if a tube gets a punctured wound caused by a nail or the like, air in the tube is leaked from the punctured wound through a small clearance between the tire and the tube and via.a. nipple bore in the rim to the outside and, the tire becomes flat.
Therefore, there is a conventionally known a tube-incorporated tire including a liquid sealant- which is previously injected in an appropriate amount for automatic emergence repairing of a puncture when the tube is punctured (see Japanese Patent Application Laid-open No.58-74342). [Problems to be solved by the Invention]
In the above known tire, however, a capsule filled with the sealant is incorporated into the tube in forming the tube, and after the formation, the capsule is broken to charge the sealant into the tube. For this reason, when an external force
is applied to break the capsule, not only the tube is prone to be damaged, but also the sealant may clog an air valve of the tube, and may clog a pressure gauge when an air pressure within the tube is measured.
To solve this problem, the inside of the tube may be divided into an air chamber filled with air, and a sealant chamber filled with the sealant, and the sealant may be charged directly into the sealant chamber without use of a capsule. Accordingly, it is an object of the present invention to provide a process for efficiently producing a sealant-contained tire tube including an air chamber and a sealant chamber. [Approach to solve the Problems]
To achieve the above object, according to claim 1 of the present invention, there is provided a process for producing a sealant-contained tire tube including an air chamber filled with air and a sealant chamber filled with a sealant, step for process comprising: a first step for extruding a tube blank including a peripheral wall of a circular section in which an air chamber and a sealant chamber are defined by a partition wall; a second step for bonding step for tube blank at its opposite ends into an annular shape; a third step for forming a sealant charging bore in step for peripheral wall to communicate with step for sealant chamber; a fourth step for charging the sealant into step for sealant chamber through step for sealant charging bore in a state in which air has been charged into step for air chamber; and a fifth step for closing step
for sealant charging bore formed in step for peripheral wall.
According to claim 2, in addition to claim 1, the air is charged into the air chamber through an air valve mounted in the peripheral wall at the fourth step.
According to claim 3, in addition to claim 1, a raw rubber sheet is affixed to the sealant charging bore and vulcanized to close the sealant charging bore.
According the invention as defined in claim 4, there is provided a process for producing a sealant-contained tire tube including an air chamber filled with air and defined between a partition wall and an air chamber peripheral wall constituting a half periphery of a peripheral wall having a circular section by partitioning the inside of the peripheral wall, and a sealant chamber filled with a sealant and defined between the partition wall and a sealant chamber peripheral wall constituting a remaining half peripheral of the peripheral wall, the process comprising: a first step of forming a tube blank by extrusion, such that a free length of the partition wall is substantially equal to a free length of the air chamber peripheral wall and a free length of the sealant chamber peripheral wall; a second step of cutting the tube blank into a predetermined length; a third step of compressing opposite ends of the tube blank in a diametrical direction to superpose the air chamber peripheral wall, the partition wall and the sealant chamber peripheral wall into three layers; and a fourth step of bringing the compressed opposite ends of the tube blank into pressure contact with each
other to bond t;hem/
According to the invention as defined in claim 5, in addition to claim 4, the tube blank is formed by extrusion at the first step, such that the section of the partition wall is corrugated.
[BRIEF DESCRIPTION OF THE DRAWINGS]
[Fig.l]
A cross-sectional view of a wheel on which a tube-incorporated tire is mounted [Fig.2]
A view showing tube-producing steps [Fig.3j
A cross-sectional view of a tube blank [Fig.4)
A partial sectional view of an extruder [Fig.5]
An enlarged view taker, along the arrow 5 [Fig.6]
A side view of a splicer
[Fig.7]
An enlarged view taken along the line 7-7 in Fig.6 [Fig.8]
A sectional view of a heating die. [Fig.9)
A view showing another embodiment of th« tube blank
[Embodiment]
The present invention will now be described by way of a preferred embodiment with reference to the accompanying drawings.
Figs.l to 8 show a first embodiment of the present invention, wherein: Fig.l is a cross-sectional view of a wheel on which a tube-incorporated tire is mounted; Fig.2 shows tube-producing steps; Fig.3 is a cross-sectional view of a tube blank; Fig.4 is a partial sectional view of an extruder; Fig.5 is an enlarged view taken along the arrow 5; Fig.6 is a side view of a splicer; Fig.7 is an enlarged view taken along the line 7-7 in Fig.6; and Fig.8 is a sectional view of a heating die.
Referring to Fig.l, a rim R of a wheel for a motorcycle is connected to a hub (not shown) through a wire spoke. A tube-incorporated tire T including a tire 1 and a rube 2 contained in the tire 1 is mounted on the rim R. The tube 2 includes a peripheral wall 4 which is formed to have an annular section and which includes an air chamber peripheral wall portion 4i located at a radially inner side and a sealant chamber peripheral wall portion 4o located at a radially outer side.
A pair of connections connecting the air chamber peripheral wail portion 4i and the sealant chamber peripheral wall portion 4o of the peripheral wall 4 are connected to each other by a partition wall 5 which is formed integrally with the connections.
Air is filled in an air chamber 3 which is substantially circular in section and which is defined between the air chamber peripheral wall portion 4i and the partition wall 5. A known liquid sealant 8 is filled in a sealant chamber 7 which is substantially arcuate in section which is defined between the sealant chamber peripheral wall portion 4o and the partition wall 5. The air chamber peripheral wall portion 4i is provided with an air valve 6 for charging air into the air chamber 3. The sealant chamber 7 in the tube 2 is maintained in a shape extending along an inner surface -of the tire 1 by an air pressure in the air chamber 3. Hence, even if a centrifugal force is applied to the sealant filled in the sealant chamber 7 during rotation of the wheel, the sealant 8 can be prevented from being offset toward an outer periphery of the tube 2. Therefore, even if the tube gets a punctured wound radially or sideways by a nail or the like, the sealant 8 immediately fills the punctured wound to repair the tube 2, thereby retarding the leakage of air from the air chamber 3. The sealant 8 is retained in the sealant chamber 7 and cannot flow into the air chamber 3 and hence, the sealant 8 cannot clog the air valve 6, a pressure gauge mounted to the air valve and the like.
A process for producing the rube 2 will be described below.
As shown in Fig.2, the process for producing the cube 2 includes a material kneading step, a tube blank extruding step, a cutting step, an air valve mounting step, a bonding step, a first vulcanizing step, a boring step, a sealant charging step, a raw rubber sheet affixing step, a second vulcanizing step and an inspecting step.
First, a material resulting from the kneading at the material kneading step is subjected to an extrusion at the tube blank extruding step, thereby forming a tube blank 2' made of a raw rubber. As shown in Figs. 3 to 5, the tube blank 2' continuously extruded from a nozzle 12 of an extruder II includes a peripheral wall circular in cross section, and a partition wall 5 connecting two points of the peripheral wall 4 located on a diametrical line, in a wave-like shape. In other words, the peripheral wall 4 is divided, at a boundary provided by the connection between the peripheral wall 4 and the partition wall 5, into an air chamber peripheral wall portion 4i and a sealant chamber peripheral wall portion 4o. The length Li of the air chamber peripheral wall portion 4i, the length Lo of the sealant chamber peripheral wall portion 4o and the length Lc of the partition wall 5 are set at substantially equal values. By forming the partition wall 5 into a wave-like shape, the above length Lc can be insured without creation of a steep bent portion.
The nozzle 12 of the extruder 11 for extruding the tube blank 2' has two mold release agent discharge ports 13 and two mold release agent intake ports 14 provided therein for discharging and supplying a mold release agent such as talc from and to the air chamber 3 and the sealant chamber 7. By forming the air chamber 3 and the sealant chamber 7 into the same sectional area by the partition wall 5 having the wave-like cross section, a space for disposition of the mold release agent discharge ports 13 and the mold release agent intake ports 14 can be easily insured.
At the subsequent cutting step, the tube blank 2' is cut into a predetermined length and then, at the air valve mounting step, the air valve 6 is mounted at place to the air chamber peripheral wall 4i. Further, at bonding step, the opposite ends of the tube blank 2' are bonded. ' '
Figs. 6 and 7 show a splicer used at the bonding step. The opposite ends of the tube blank 2' are clamped by a cramp 17 comprised of a pair of cramp members 15 and 16, such that the opposite ends of the tube blank 2' slightly protruding from the clamp members 15 and 16 are pressure-bonded to each other. The tube blank 2' made of the raw rubber before being vulcanized is bonded into an annular shape by the pressure bonding.
At this time, in order to correctly bond the air chamber peripheral wall portion 4i, the partition wall 5 and the sealant chamber peripheral wall portion 4o at one end of the tube blank 2' to the air chamber peripheral wall portion 4i, the partition
wall 5 and the sealant chamber peripheral wall portion 4o at the other end of the tube blank 2', the partition wall 5 is sandwiched between the air chamber peripheral wall portion 4i and the sealant chamber peripheral wall portion 4o and clamped by the cramp 17 to form three layers (see Fig.7) . Because all of the length Li of the air chamber peripheral wall portion 4i, the length Lc of the partition wall 5 and the length Lo of the sealant chamber peripheral wall portion 4o are set equally (see Fig.3), as described above, the air chamber peripheral wall portion 4i, the partition wall 5 and the sealant chamber peripheral wall portion 4o are clamped as being of natural lengths, without being compressed or expanded. Thus, the air chamber peripheral wall portion 4i, the partition wall 5 and the sealant chamber peripheral wall portion 4o are prevented from being wrinkled, and can be reliably bonded together.
At the next first vulcanizing step, as shown in Fig.8, the tube blank 2' is placed into a heating die 18, and the air chamber peripheral wall portion 4i and the sealant chamber peripheral wall portion 4o are brought into close contact with the heating die 18 and at the same time, the partition wall 5 is brought into close contact with the sealant chamber peripheral wall portion 4o by supplying heated air and hot steam into the air chamber 3 through the air valve 6. In this state, the heating die 18 is heated to conduct the vulcanization.
At the subsequent boring step, the sealant chamber peripheral wall portion 4o of the tube blank 2' with a selant
charging bore 4: and then, at the sealant charging step, the sealant 8 is charged through the sealant charging bore 4i into the sealant chamber 7. In this case, air is supplied through the air valve 6 into the air chamber 3 to expand the air chamber 3 prior to the charging of the sealant 8, thereby causing the partition wall 5 to be brought into close contact with the sealant peripheral wall portion 4o as in the state shown in Fig. 8 to completely discharge the air within the sealant chamber. In this state, the charging of the sealant 8 is started. In this manner, by starting the charging of the sealant 8 in the state in which the air in the sealant chamber 7 has been completely discharged, the incorporation of the air into the sealant 8 can be reliably prevented, and only the sealant 8 can be charged. In addition, since the air is supplied into the air chamber 3 by utilizing the air valve 6, it is unnecessary to open a bore used for charging the air.
Then, at the raw rubber sheet affixing step, a raw rubber sheet 19 is affixed to cover the sealant charging bore 4: and then, a portion of the tube blank 2' in the vicinity of the raw rubber sheet 19 is locally vulcanized at the second vulcanizing step to close the sealant charging bore 4:, thereby finishing a tube 2. Because the sealant charging bore 4: is closed using the raw rubber sheet 19 which is the same material as for the tube blank 2' , the strength of the closed portion can be enhanced to reliably prevent the leakage of the sealant 8. The finished tube 2 is then inspected at the inspecting step to complete the
producing process.
Although the embodiment of the present invention has been described in'detail, it will be understood that the present invention is not limited to the above-described embodiment, and various modifications may be made without departing from the subject matter and scope of the invention defined claims.
For example, the shape of the partition wall 5 in forming the tube blank 2' by extrusion is not limited to the wave-like shape in the embodiment and may be another wave-like shape as shown in Fig.9.
[Effect of the Invention]
According to the invention as defined in claim 1, as described above, the tube blank including the air chamber and the sealant chamber defined by dividing the inside of the peripheral wall having the circular section is formed by extrusion, and the sealant is charged into the sealant chamber. Thereafter, the sealant.charging bore is closed. Therefore, the air chamber and the sealant chamber can be reliably separated from each other, while preventing a damage of the tube, and the sealant can be prevented from clogging an air valve and from being leaked. In addition, since the sealant is charged into the sealant chamber through the sealant charging bore in the state in which the air has been charged into the air chamber, the air can be expelled from the sealant chamber prior to the charging of the sealant to avoid the mixing of the sealant with the air.

According to the invention as defined in claim 2, because the air is charged into the air chamber through an air valve mounted in the peripheral wall at the fourth step, the need for provision of a special air-charging bore in the peripheral wall can be eliminated, leading to a reduced number of fabricating steps.
According to the invention as defined in claim 3, because a raw rubber sheet is affixed to the sealant charging bore and vulcanized to close the sealant charging bore, the sealant charging bore can be reliably closed to prevent the leakage of the sealant.
According to the invention as defined in claim 4, the air camber and the sealant chamber can reliably separated from each other to prevent the leakage of the sealant by the fact that the air chamber filled with air is defined between the air chamber peripheral wall constituting the half periphery of the peripheral wall and the partition wall, and the sealant chamber filled with the sealant is defined between the sealant chamber peripheral wall constituting the remaining half periphery of the peripheral wall and the partition wall. In addition, the tube blank is formed by extrusion, such that the free length of the partition wall is substantially equal to the free length of the air chamber peripheral wall and the free length of the sealant chamber peripheral wall, and therefore, in compressing the opposite ends of the tube blank cut into the predetermined length in the diametrical direction to superpose the air chamber
peripheral wall, the partition wall and the sealant chamber peripheral wall into the three layers, the air chamber peripheral wall, the partition wall and the sealant chamber peripheral wall can be prevented from being wrinkled, thereby reliably performing the bonding.
According to the invention as defined in claim 5, the tube blank is formed by extrusion, such that the section of the partition wall is corrugated. Therefore, it is possible of insure a required length of the partition wall, while preventing a sharp bending of the partition wall. (Explanation of Reference Numerals]
2' tube blank
3 air chamber
4 peripheral wall
4: sealant
41 peripheral wall of air chamber
4o peripheral wall of sealant chamber
5 partition wall
6 air valve
7 sealant chamber
8 sealant
19 raw rubber sheet

[ciaim l] A process for producing a sealant-contained tire
tube including an air chamber (3) filled with air and a sealant chamber (7) filled with a sealant (8), said process comprising:
a first step for extruding a tube blank (21) including a peripheral wall (4) of a circular section in which an air chamber (3) and a sealant chamber (1) are defined by a partition wall (5);
a second step for bonding said tube blank (21) at its opposite ends into an annular shape;
a third step for forming a sealant charging bore (4-J in said peripheral wall to communicate with said sealant chamber (7);
a fourth step for charging the sealant (8)' into said sealant chamber (7) through said sealant charging bore (4;) in a state in which air has been charged into said air chamber (3) ; and
a fifth step for closing said sealant charging bore (4-J formed in said peripheral wall.
[Claim 2] A process for producing a sealant-contained tire
tube according to claim 1, wherein the air is charged, at said fourth step, into said air chamber (3) through an air valve (6)
mounted in said peripheral wall (4).
[Claim 3] A process for producing a sealant-contained tire
tube according to claim 1, wherein a raw rubber sheet (19) is affixed to said sealant charging bore (4;) and vulcanized to close said sealant charging bore (4i).
[Claim 4] A process for producing a sealant-contained tire
tube including an air chamber filled with air and defined between a partition wall and an air chamber peripheral wall constituting a half periphery of a peripheral wall having a circular section by partitioning the inside of the peripheral wall, and a sealant chamber filled with a sealant and defined between the partition wall and a sealant chamber peripheral wall constituting a remaining half peripheral of the peripheral wall/ said process comprising: a first step of forming a tube blank by extrusion/ such that a free length of the partition wall is substantially equal to a free length of the air chamber peripheral wall and a free length of the sealant chamber peripheral wall; a second step of cutting the tube blank into a predetermined length; a third step of compressing opposite ends of the tube blank in a diametrical direction to superpose the air chamber peripheral wall/ the partition wall and the sealant chamber peripheral wall into three layers; and a fourth step of bringing the compressed opposite ends of the tube blank into pressure- contact with each other to bond them.
[Claim 5] A process for producing a sealant-contained tire
tube according to claim 4, wherein said tube blank is formed by
extrusion at said first step, such that the section of the partition wall is
corrugated.
6. A process for producing a sealant-contained tire tube substantially
as hereinbefore described with reference to and as illustrated in the
accompanying drawings.

Documents:

2681-del-1996-abstract.pdf

2681-del-1996-claims.pdf

2681-DEL-1996-Correspondence Others-(03-06-2011).pdf

2681-del-1996-Correspondence Others-(30-11-2012).pdf

2681-del-1996-Correspondence-Others-(06-04-2011).pdf

2681-del-1996-correspondence-others.pdf

2681-del-1996-correspondence-po.pdf

2681-del-1996-description (complete).pdf

2681-del-1996-drawings.pdf

2681-del-1996-form-1.pdf

2681-del-1996-form-13.pdf

2681-del-1996-form-19.pdf

2681-del-1996-form-2.pdf

2681-del-1996-form-3.pdf

2681-del-1996-form-4.pdf

2681-del-1996-form-6.pdf

2681-del-1996-GPA-(30-11-2012).pdf

2681-del-1996-gpa.pdf

2681-del-1996-petition-137.pdf

2681-del-1996-petition-138.pdf

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Patent Number

214549

Indian Patent Application Number

2681/DEL/1996

PG Journal Number

08/2008

Publication Date

22-Feb-2008

Grant Date

12-Feb-2008

Date of Filing

03-Dec-1996

Name of Patentee

HONDA GICKEN KOGYO KABUSHIKI KAISHA

Applicant Address

1-1 MINAMIAOYAMA 2 CHOME,MINATO-KU, TOKYO, JAPAN

Inventors:

#	Inventor's Name	Inventor's Address
1	TOSHIO YAMAGIWA	C/O KABUSHIKI KAISHA HONDA GIGUTSU KENKYUSHO OF 4-1 CHUO 1-CHOME, WAKO-SHI, SAITAMA, JAPAN

PCT International Classification Number

B29C 73/20

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	HEI-7-339371	1995-12-26	Japan