JP2012210930A - No flat tube - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a flat tube which is reduced in weight while possessing conflicting nature between the side offset yield stress of a tire and a cushioning property.SOLUTION: There is provided a constitution where a tube C1 is formed by elastomer when viewed in a cross section, sides 2 are connected to both sides of grounding section 1, respectively, a space between each side 2 is profiled in an opened roughly-U character, and formed straight so that it may has a length slightly longer than a peripheral length of the center K of annular space 22 of a tire skin 21, the tube C1 is arranged in the annular space 22 of the tire skin 21 so that an opening side may face a rim 23 with an original profile while the tube C1 is profiled in straight, and in such a state that the each side 2 is embedded by deforming it largely elastically when viewed in the cross section, both end surfaces in the longitudinal direction are confronted in such a manner that they push each other in opposite directions.

Description

  The present invention is a straight tube that uses elastomer as a raw material and does not require joining at both end portions, and has a property that conflicts with the side strength of the tire and the cushioning property, and is a no puncture that is reduced in weight. It relates to tubes. The no-puncture tube according to the present invention is used by being fitted into tires of bicycles, wheelchairs, senior cars and the like.

  A tube disclosed in Patent Document 1 is known as one of tubes that do not puncture even when nails are pierced (no puncture tube). This tube is a single extruded piece, and has a length of 1.00 to 1.03 times the circumferential length of the center of the annular space portion of the tire skin, and 1 with respect to the cross-sectional area of the annular space portion. It has a cross-sectional area of 0.0 to 1.3 times, and is slightly expanded in the circumferential direction by being slightly compressed in the cross section by fitting the tube into the annular space portion. By accommodating the two end surfaces in a state of being abutted against each other, it is not necessary to join the both ends of the tube by heat fusion, and each one corresponding to various tire sizes such as a ring-shaped tube can be used. No longer need to be manufactured, and by cutting the extruded long tube material into the circumferential length of the tire outer shell, it can be fitted into tires of various sizes.

  However, the cross-sectional shape of the tube before fitting is a solid structure with a circular cross-section or a structure with a hole in which a large number of small holes are continuously formed in the longitudinal direction. By compressing and deforming, the tube was in close contact with almost the entire inner peripheral surface of the tire outer skin. Therefore, since the annular space portion of the tire skin is filled with a tube that is compressed and deformed as a whole, there is a problem that the weight of the tube increases and the weight of the tube cannot be reduced. For example, a tube having a solid structure using a thermoplastic elastomer corresponding to a tire of size (26 × 1 3/8) has a weight of about 1300 g, which is somewhat heavy as a bicycle tube. Therefore, it has been desired to reduce the weight of this type of straight tube. Here, by providing a large number of small holes, the weight can be reduced somewhat. However, if the void ratio, which is the ratio of the small hole area to the tube cross-sectional area, exceeds 25%, the pressure from the ground plane during use As a result, the degree of deformation of the tube that is deformed in response to the deformation becomes too large, resulting in poor ride comfort, and the tube itself becomes fragile, resulting in a decrease in durability. For this reason, the porosity of the tube cannot be increased too much, and this point also hinders the weight reduction of the tube.

Japanese Patent No. 4392555

  In the present invention, the use of the elastic deformation of the entire tube having a substantially U-shaped section or a ring-shaped section in which each side surface portion is connected to both sides of the grounding portion, the contradictory properties of the tire side load resistance and cushioning properties. In addition, the challenge is to provide a no-punk tube that is lighter in weight.

  The invention of claim 1 for solving the above-mentioned problem is a tube that is deformed and fitted in a cross-sectional view while keeping a straight shape in an annular space portion of an annular tire skin that is detachably attached to an annular rim. The tube is formed of an elastomer, and has a substantially U shape in which a side surface portion is connected to both sides of the grounding portion in a cross-sectional view and an opening is formed between the side surface portions. The tube is formed in a straight shape so as to have a length slightly longer than the circumferential length of the center of the annular space portion, and the tube is kept straight in the annular space portion of the tire outer cover, and the opening side is the original shape. The tube is arranged so as to face the rim, and in a state where the side portions are elastically deformed and fitted in a cross-sectional view, both end surfaces in the longitudinal direction of the tube are pressed against each other in a direction opposite to each other. Specially It is set to.

  Since the tube of claim 1 is fitted into the annular space portion of the tire skin while being straight, both ends thereof are not joined, and thus remain straight and do not form a ring. After removing the tire skin from the tire rim, each side portion of the tube so that the opening formed between the side portions of the tube faces the opening side of the tire skin (the rim side in the assembled state). Is elastically deformed inward so as to be close to each other, and is fitted into the annular space of the tire outer skin. Thereby, the grounding part of a tube and each side part of the both sides of the said grounding part closely_contact | adhere to the inner peripheral surface of a tire outer skin, respectively. Since the length of the tube is slightly longer than the circumferential length of the center of the annular space portion of the tire outer skin, the tube fitted in the annular space portion of the tire outer skin is along the circumferential direction. Although there is a slight “weight allowance”, the “weight allowance” disappears when both end faces of the tube are pressed against each other and compressed. As a result, the tube fitted in the annular space portion of the tire skin in a straight shape can be separated along the circumferential direction, or the cross section of the tube, even if the both end portions are not joined together. The ring shape is maintained without shifting each end from the view. In addition, in a state where the tube is fitted in the annular space portion of the tire skin, the tire skin is hooked on the catch portion of the rim, and the rim and the tire skin are assembled to obtain a tire.

  The grounding part of the tube is arranged inside the grounding part of the tire skin, and each side part of the tube is greatly elastically deformed and arranged inside the both side parts of the tire skin to elastically contact the inner peripheral surface. Yes. Due to the force of each side surface portion of the tube elastically contacting the inner peripheral surface of the tire outer skin, the ground contact portion of the tube also elastically contacts the inner peripheral surface of the tire outer skin. With the tube fitted in the annular space of the tire skin, the openings formed between the side surfaces of the tube remain narrowed by the inward elastic deformation of the side surfaces. Yes. For this reason, the elastic restoring force of each side portion of the elastically deformed tube continues to act as a tension force on both side portions of the tire skin, so that the shape of both side surfaces of the tire easily collapses at normal contact pressure. "Side resistance" that is the power to prevent By the above-mentioned tensioning action of each side surface portion of the tube, the shape of both side portions of the tire outer skin can be maintained, and each side surface portion is fitted into the annular space portion of the tire outer skin in a state of being elastically deformed inwardly. The entire tube is elastically deformed to absorb the grounding force due to the grounding force that the running tire receives from the ground, so the tire as a whole has a cushioning property that is a comfortable rebound resilience. This ensures a comfortable ride. In addition, as a whole tube, each side portion is elastically brought into contact with the inner peripheral surface of both side portions of the tire skin by its own tensile force while maintaining a substantially U-shaped cross section, and both end surfaces are stretched against each other. Therefore, the cross-sectional shape of the ring-shaped tube is slightly elastically deformed by the ground contact force, but the ring shape, which is the overall shape of the tube, is because the cross-section is substantially U-shaped. Because of the shape retention rigidity that retains the overall shape, the entire ring shape is firmly maintained without being destroyed at all even if a grounding force is applied.

  As described above, the tube according to the invention of claim 1 has a cushioning property that, when fitted into the tire outer shell, has side strength as a tire and elastically deforms while absorbing the grounding force. And since the ratio of the hollow part in the cross-sectional view of the said tube can be enlarged, maintaining the original function of a tube, the weight reduction of a tube is attained.

  The invention of claim 2 is characterized in that, in the invention of claim 1, the opening of the hollow portion of the tube is narrowed and remains in a state in which the tube is fitted in the annular space portion.

  According to the invention of claim 2, due to the presence of the remaining opening, each side portion of the tube fitted in the annular space portion of the tire skin is elastically deformed in a state where each side portion is greatly elastically deformed inward. Therefore, the cushioning property is further increased.

  According to a third aspect of the present invention, in the first aspect of the present invention, in the state where the tube is fitted in the annular space portion, the end portions of the side surface portions of the tube are in contact with each other in a cross-sectional view. It is said.

  According to the invention of claim 3, even if the end portions of the side surface portions of the tube are in contact with each other, each side surface portion tends to be deformed to the outside, so that each side surface portion of the tube tends to be restored by elastic force. The action, i.e., the tension force on each side portion of the tire skin by each side portion of the tube is not reduced at all, and the end portions of each side portion of the tube are in contact with each other, and the shape of the elastically deformed tube is In order to stabilize, the said side load resistance as a tire increases. As a result, the integrity between the tube and the tire outer shell is increased, and the cushioning property as a tire is increased. Further, when the tube is fitted into the annular space portion of the tire skin, the outer portion of the tube is pulled and extended along the circumferential direction, and the end portion of each side surface portion that is the inner portion is in the circumferential direction. Is compressed along the circumferential direction, so that wrinkles are generated along the circumferential direction, and a slight gap is generated between the inner circumferential surface of the tire outer skin. Since they are in contact with each other, the generation of the wrinkles can be suppressed, and the entire surface of each side surface portion of the tube can be easily adhered to the inner peripheral surface of the side surface portion of the tire skin. As a result, the integrity between the tube and the tire outer shell is increased, and the cushioning property as a tire is increased.

  According to a fourth aspect of the present invention, in the invention according to any one of the first to third aspects, the tube gradually decreases in thickness from the center of the grounding portion toward both ends in a cross-sectional view.

  According to the invention of claim 4, the thickness of the grounding portion of the tube on which the greatest grounding force acts is large and the thickness gradually decreases toward the tip of each side surface portion. In addition, both side portions of the tire are easily deformed with respect to the contact pressure, and riding comfort is enhanced.

  The invention according to claim 5 is a tube that is detachably attached to an annular rim and is fitted into the annular space portion of the annular tire skin that is deformed and fitted in a cross-sectional view in a straight shape. The tube is formed from an elastomer and is formed in a straight shape so as to have a length slightly longer than the circumferential length of the center of the annular space portion of the tire outer skin. In the state where each tube is elastically deformed and fitted in the cross-sectional view while the tube remains in a straight shape in the annular space, both end faces in the longitudinal direction of the tube are pressed against each other in a direction opposite to each other. It is characterized by being.

  In a state where the hollow pipe-like tube according to the invention of claim 5 is fitted in the annular space portion of the tire skin, each portion that has formed a ring shape in a cross-sectional view before fitting is formed in the opening of the tire skin. In a state where the compressive deformation rate of only the corresponding portion is slightly small, the whole is compressed and deformed, and is in close contact with the inner peripheral surface of the tire outer skin. This state is substantially the same state as that of the tube according to the invention of claim 3 in which both ends of each side surface portion are in contact with each other in a state of being fitted in the annular space portion of the tire skin, and in a cross-sectional view. Each part of the tube functions as a grounding part corresponding to the grounding part of the tire, side parts connected to both sides of the grounding part, and a connecting part that connects the side parts. Due to the presence of the connecting part that connects each side part, the side strength increases, and even if it receives a large or abrupt grounding force, both side parts of the tire exceed the limit of elastic deformation, so the shape does not collapse, In addition to having a high lateral proof stress, the cushioning properties are good, and there is an advantage that no wrinkles are generated when a single tube is bent into a ring shape and fitted into a tire skin. Furthermore, the tube is in the shape of a hollow pipe, and the thickness in the cross sectional view may be a thickness that can ensure the side strength and good cushioning properties, and in the case of a thickness exceeding the thickness, The side load resistance is excessively increased, the cushioning property is lowered, and the thickness of the grounding portion is excessively increased, which causes vibrations and the ride comfort is deteriorated. Durability is also reduced. Therefore, the thickness of the tube in the cross-sectional view is sufficient as long as it can secure the above-mentioned side strength and good cushioning properties, so that the ratio of the hollow portion (porosity) in the cross-sectional view can be increased. The weight of the tube can be reduced. The butted state of both end faces in the longitudinal direction of the tube is almost the same as that of the tube of claim 1.

  The invention of claim 6 is the invention of claim 5, wherein the tube has a ring-shaped cross section, and the center of the hollow portion is eccentric with respect to the center of the solid portion, and extends over the entire circumference. The thickness is changed, and the largest thickness portion is a ground contact portion arranged in the ground contact portion of the tire skin.

  According to the invention of claim 6, since the thickness of the grounding portion is thicker than the thickness of other portions, when the porosity and material are the same, the center of the whole and the center of the hollow portion As compared with the same hollow pipe shape, the lateral strength can be increased.

  According to a seventh aspect of the present invention, in the invention of the sixth aspect, a positioning ridge that performs positioning in the circumferential direction when fitted into a tire outer skin is continuous in a longitudinal direction at a portion of the outer peripheral surface of the tube facing the ground contact portion. It is characterized by being formed.

  Since the tube which concerns on invention of Claim 6 has directionality when it fits in a tire outer skin, when the protrusion of a longitudinal direction is provided in the outer peripheral surface of a tube like invention of Claim 7, Since the protrusions are arranged in the opening of the tire skin, the arrangement in the fitted state of the tubes having different thicknesses along the circumferential direction can be visually specified. Further, the protrusion provided on the outer peripheral surface of the tube can be automatically formed when the tube is extruded.

  The invention of claim 8 is the invention according to any one of claims 1 to 7, wherein a connecting core member made of an elastomer having a hardness smaller than the hardness of the tube is provided in each hollow portion at both ends in the circumferential direction of the tube. The both ends of the tube in the circumferential direction are fitted to each other in a state where both ends of the tube are connected to each other via the connecting core member.

  According to the invention of claim 8, in the state where the tube is fitted in the annular space portion of the annular tire outer shell, both end portions in the circumferential direction of the tube have a hardness smaller than the hardness of the tube in each hollow portion. The connection core material which consists of elastomers is engage | inserted, and it mutually connects via the said connection core material. For this reason, the both end surfaces in the circumferential direction of the tube are pressed against each other in the opposite direction in a state where both ends in the circumferential direction of the tube are connected to each other via the connecting core member. For this reason, the shape holding force at both ends of the tube is increased, and the cross-sectional shape can hold the same shape as other general parts firmly. This eliminates the phenomenon of subtle discomfort and improves ride comfort when used for bicycle tires.

  According to a ninth aspect of the present invention, in the eighth aspect of the present invention, the center portion in the longitudinal direction of the connecting core member is provided with a slip prevention collar portion that prevents the connecting core member from being displaced along the circumferential direction of the tube. It is characterized by being integrally formed.

  According to the ninth aspect of the present invention, in the state in which the shift prevention flanges integrally formed at the center portion in the longitudinal direction of the connecting core member are sandwiched between the both end faces of the tube, the length of the tube is interposed via the connecting core member. Since both ends of the direction are connected, the connecting core material separate from the tube is not displaced in the circumferential direction of the tube even after long-term use.

  The invention of claim 10 is characterized in that, in any one of the inventions of claims 1 to 9, the elastomer is a thermoplastic elastomer.

  In the invention of claim 10, since the thermoplastic elastomer is generally excellent in both elasticity and extrudability, it is suitable as a material for the tube of any one of claims 1 to 9.

  An eleventh aspect of the invention is characterized in that, in any one of the first to tenth aspects of the invention, the Shore A hardness of the elastomer is 40 to 90.

  The tube according to any one of claims 1 to 10 has a substantially U-shaped cross section or a hollow pipe shape, and has a large void ratio, so that it has a necessary lateral strength when fitted into a tire skin. In order to obtain it, the tube material requires a certain degree of hardness. However, if the hardness of the material of the tube is too large, the lateral strength is increased, but the cushioning property as a tire is lowered and the impact force is increased. As described above, the hardness of the material of the tube having both the side load resistance and the cushioning property as the tire is in the range of Shore A hardness of 40 to 90.

  The tube according to the first to fourth aspects of the present invention has a U-shaped cross section, and the side surfaces connected to both sides of the grounding portion are greatly elastically deformed inward, whereby the inner peripheral surface of the tire outer skin. The side proof stress is ensured by the elastic restoring force that the respective side portions are restored to the outside and the hardness of the elastomer that is the material forming the tube, and the elastic restoring force. In addition, a cushioning property is obtained by the elasticity of the elastomer that is the material of the tube. Thus, by using a tube having a U-shaped cross section, the porosity can be increased and the weight of the tube can be reduced.

  The tube according to the inventions of claims 5 to 7 has a hollow pipe shape, and is continuously compressed in a cross-sectional view in a state where the tube is slightly compression-molded and fitted in an annular space portion of a tire outer cover in a cross-sectional view. In addition, the hardness of the elastomer, which is the material used to form the tube, can provide side tire strength and cushioning properties as a tire, so the porosity of the tube can be increased and the tube weight reduced. Is planned.

  In the tubes according to the eighth and ninth aspects of the present invention, the connecting core material is fitted into the hollow portions at both ends in the circumferential direction, and both end portions of the tube are connected via the connecting core material. Both end portions in the circumferential direction also have the same shape retention force as other general portions, so that riding comfort is enhanced when used in a bicycle or the like.

(A), (b) is a front view, and a partially enlarged perspective view of a tube long member C _0, respectively. It is a cross-sectional view in the non-deformation of the tube C ₁ obtained by cutting the tube long member C ₀ to the setting length. FIG. 3 is a cross-sectional view in which a tube C ₁ is deformed and fitted into an annular space 22 of a tire outer skin 21 removed from a rim 23. FIG. 3 is a cross-sectional view of a state in which a tire outer skin 21 fitted with a tube C ₁ is assembled to a rim 23 to become a tire T ₁ . It is a front view of a partially cutaway of a tire T _{1. 1 is} an overall perspective view of a tube C ₁ that is deformed in a cross-sectional view and is bent into a ring shape and fitted into a tire outer skin 21. FIG. It is a schematic diagram of the state by which the tube elongate material _C0 is extrusion-molded. It is a cross-sectional view of the tire T ₁ that tube C ₂ was used. Tube C ₃ is a cross-sectional view of the tire T ₁ used. It is a cross-sectional view of the tire T ₁ that tube C ₄ was used. It is a cross-sectional view of tire T ₂ of a senior car. It is a figure which shows the relationship between the change of the thickness in the cross sectional view of a tube, and various characteristics of a tube. (A), (b), (c) is a perspective view of a tube C ₁ -C _4, circumferential connecting core used for linking both ends of the C ₁₁ E ₁ ~E _3. It is a perspective view of the connecting core E ₁ of the circumferential direction of the both end portions and the hollow short pipe-shaped pipe-like tube C _3. FIG. 3 is a longitudinal sectional view showing a state in which both ends in the circumferential direction of a pipe-like tube C ₃ are connected via a hollow short pipe-like connecting core member E ₁ in the tire outer skin 21. It is a cross-sectional view similarly. FIG. 3 is a longitudinal sectional view showing a state in which both ends in the circumferential direction of a pipe-like tube C ₃ are connected via a connecting core member E ₂ having a star-shaped cross section in the tire outer skin 21. FIG. ₃ is a longitudinal sectional view showing a state in which both end portions in the circumferential direction of a tube C ₁ having a substantially U-shaped cross section in the tire outer skin 21 are connected via a connecting core material E ₃ .

Hereinafter, the present invention will be described in more detail with reference to a plurality of tubes C _{1 to} C ₄ having a cross-sectional shape.

Hereinafter, the present invention will be described in more detail. As shown in FIGS. 1 and 2, the tube C _{1 according} to the present invention is fitted into an annular space 22 (see FIG. 3) formed in the tire outer skin 21 of the bicycle tire T ₁ . The tube C ₁ has a U-shaped cross section, and is connected to the grounding portion 1 disposed inside the grounding portion of the tire skin 21 and to both sides of the grounding portion 1. And side surface portions 2 disposed on the inner sides of the two side portions. The thickness of the tube C ₁ is such that the central portion of the grounding portion 1 has the maximum thickness (t ₁ ), and the thickness gradually decreases from the central portion of the grounding portion 1 toward the end of each side surface portion 2. In other words, the end wall portion of each side surface portion 2 has a minimum thickness (t ₂ ). Further, as shown in FIG. 2, the cross-sectional shape of the tube C ₁ before being fitted into the annular space portion 22 of the tire outer skin 21 is the cross-sectional shape (inner peripheral surface shape) of the annular space portion 22. The entire side including the grounding portion 1 is slightly elastic after the side portions 2 are greatly elastically deformed inward so that the whole is slightly larger and the interval between the end portions of the side portions 2 is narrowed. By deforming, the tube C ₁ is shaped to be fitted into the annular space 22 of the tire outer skin 21.

The tube C ₁ is made of a long tube material C ₀ extruded by using an elastomer as a material, and the center K of the annular space 22 of the tire outer skin 21 (the neutral surface of the tube C ₁ fitted into a ring shape). It has a long shape having a length (L) corresponding to the circumference of the existing position (see FIG. 4). Here, “the length (L) corresponding to the circumferential length of the center K of the annular space 22 of the tire outer skin 21” refers to the circumferential length (L ₀ ) of the center K of the annular space 22 of the tire outer skin 21. The length of [(1.01-1.03) × L ₀ ]. The cut length (L) of the tube C ₁ may theoretically be the circumferential length (L ₀ ) of the center K of the annular space 22 of the tire outer skin 21, but the cutting error of the extruded long tube material may be reduced. Considering this, it is desirable to cut longer as described above.

The elastomer as the material of the tube C ₁ has necessary side strength and elasticity (cushioning property) having good ride comfort when the tire T ₁ is fitted into the annular space 22 of the tire outer skin 21. If it is a thing, all elastomers including rubber can be used, but TPE (thermoplastic elastomer) is suitable in consideration of the original elastic characteristics, lightness, productivity, availability of raw materials, etc. Styrenic thermoplastic elastomers are particularly suitable. A styrenic thermoplastic elastomer suitable for the present invention is a block polymer composed of a polystyrene block and an elastomer block having a polyolefin structure, which is a polystyrene-poly (ethylene / propylene) block (SEP) and a polystyrene-poly ( Ethylene / propylene) block-polystyrene (SEEPS). In addition to the styrene thermoplastic elastomers described above, SBS (styrene-butadiene-styrene copolymer), SEBS (styrene-ethylene-butadiene-styrene copolymer), SEBC (styrene-ethylene-butadiene-high crystalline ethylene copolymer). Polymer), SEPS (styrene-ethylene-propylene-styrene copolymer) and the like can be used similarly. Further, as other TPE, urethane (TPU), olefin (TPO), amide (TPAE), ester (TPEE), vinyl chloride (TPVC) and the like can be used.

Further, regarding the hardness of the elastomer, the Shore A hardness is desirably within the range of 40 to 90, and preferably within the range of 50 to 80. The hardness of the elastomer needs to be higher than the hardness of the elastomer used in the solid cross-sectional shape disclosed in Patent Document 1 or the semi-solid tube in which a plurality of small holes are continuously provided in the longitudinal direction. There is. The reason is that, since the tube of Patent Document 1 has the above-mentioned cross section, when the tube is fitted into the annular space 22 of the tire outer skin 21, almost the entire cross section is compressed and deformed, and the cross section is solid. Since the quasi-solid state is formed, the side surface strength of the tire can be obtained even if the hardness of the elastomer is relatively small, whereas the cross-sectional shape of the tube C ₁ of the present invention is U-shaped, This is because the tire has a structure that obtains the lateral strength of the tire largely depending on the elastic restoring force of each of the ground contact portion 1 and each side surface portion 2 (particularly, each side surface portion 2). In other words, the hardness of the elastomer itself must be a structure that contributes not only to the elastic restoring force of the ground contact portion 1 and each side surface portion 2 of the tube C ₁ but also to the side surface strength of the tire. However, for the tire T _{1, it} is necessary to inherently consider the ride comfort when the tire T ₁ is subjected to contact pressure. The tire T _{1 has} the necessary lateral strength and the ride comfort (cushion). The hardness of the elastomer is as described above in order to ensure both of the properties. The elastomer may be foamed as long as the hardness is secured within the range of 40 to 90 in Shore A hardness.

Next, referring to FIGS. 3 to 6, the length of [(1.01 to 1.03) × L ₀ ] with respect to the circumferential length (L ₀ ) of the center K of the annular space 22 of the tire outer skin 21. A method for fitting the tube C ₁ cut into length (L) into the annular space 22 of the tire outer skin 21 will be briefly described. As shown in FIG. 3, from the rim 23 in advance to remove the tire outer skin 21, while elastically deforming one like a tube C ₁ in cross section, is successively fitted into the annular space 22 of the tire outer skin 21 The both end surfaces are brought into contact with each other. As shown in FIG. 4, in addition to the side portions 2 of the tube C ₁ being elastically deformed inward in a cross-sectional view, connection portions between the grounding portion 1 and the side portions 2 at both ends thereof are provided. The entire tube C ₁ is elastically deformed, so that the tube C ₁ is firmly adhered to the inner peripheral surface of the annular space 22 of the tire outer skin 21 by an elastic restoring force (F ₁ ) over the entire circumference of the cross section. . On the other hand, the length (L) of the tube C ₁ is slightly longer than the circumferential length (L ₀ ) of the center K of the annular space 22 of the tire outer skin 21, and therefore the annular space 22 of the tire outer skin 21. The both end surfaces of the tube C ₁ fitted in are pressed against each other by a pressing force (F ₂ ) in opposite directions, and are brought into a butted state. In a state where the tube C ₁ is fitted in the annular space portion 22 of the tire outer skin 21, the engaged portions 21 a formed on both sides of the opening of the tire outer skin 21 are engaged with the respective engaging portions 23 a of the rim 23. The tire T ₁ is stopped. 5 and 6, 3 indicates a butt surface at both ends of the tube C ₁ , and 24 indicates a spoke of the wheel 25.

As described above, the tube C ₁ has a U-shaped cross-sectional shape in order to reduce the weight. However, the tube C ₁ has been described above in a state where the tube C ₁ is fitted into the annular space 22 of the tire outer skin 21 to form a ring shape. Thus, by elastically deforming in a cross-sectional view, the inner peripheral surface of the tire outer skin 21 is elastically contacted by an elastic restoring force (F ₁ ), and both end surfaces thereof are mutually connected along the circumferential direction. Since the pressing force (F ₂ ) in the opposite direction acts and is in a state of being abutted, in other words, in the state where the whole is in a ring shape, the elastic restoring force (F ₁ ) and the pressing force ( According to F ₂ ), the ring shape which is the entire shape and the U shape which is the cross-sectional shape are not collapsed and have a high “shape retention rigidity”. In particular, in the tube C ₁ , the thickness (t ₁ ) of the central portion of the grounding portion 1 is the thickest in a cross-sectional view, and gradually from the central portion of the grounding portion 1 toward both ends of each side surface portion 2. Since the wall thickness is small, even when a space is formed between the end portions of the side surfaces 2 of the tube C ₁ in the fitted state, sufficient side strength can be secured and cushioning can be ensured. Is also possible.

As described above, the tube C ₁ is elastically deformed in a cross-sectional view and is fitted into the tire outer skin 21, thereby providing the side load resistance and the cushioning property as the tire T ₁ . In other words, the elastically deformed tube C ₁ is provided with the side strength and cushioning properties necessary for the tire while the large hollow portion 4 (see FIG. 4) remains, and as a result, the tube C ₁ because it can increase the porosity, weight of the tube C ₁ is achieved.

Here, since the tube C ₁ is fitted in the tire outer skin 21 and a predetermined gap is formed between the end portions of the side surface portions 2, the end portions of the side surface portions 2 are long. FIG. 7 shows a state in which wrinkles are generated (a state that is slightly meandering along the longitudinal direction) without continuously contacting the inner peripheral surface of the tire outer skin 21 along the direction. As shown in the figure, immediately after being extruded from the die 31 of the extrusion molding machine 30, the tube long material C ₀ is placed along the rotation guide body 32 in an uncured state, and then the curved sheet is given and then cooled. It is possible to eliminate the generation of soot by entering the cooling water W of the water tank 33 and rapidly cooling and hardening.

  Further, as another method of eliminating the occurrence of wrinkles, in a state where the tube cut to a length corresponding to the circumferential length of the center portion of the tire outer shell is bent into a roll shape, it is heated to a predetermined temperature, There is also a method of cooling after the heating is continued at the predetermined temperature for a set time. As a result, wrinkles are not generated at the end portions of the side surfaces in a state where the tube is bent in a roll shape, so that wrinkles are not generated at the end portions of the side surface portions even when fitted to the tire outer skin.

Further, the tube C ₂ used in the tire T ₁ shown in FIG. 8 has a shape in which the side surface portions 2 ′ are connected to both sides of the ground contact portion 1 ′ in a sectional view, and is not continuous in the sectional view. Although the same as the tube C _{1 in} terms of the point, the cross-sectional shape thereof is a shape in which a part of the ring body is omitted, and by fitting into the annular space portion 22 of the tire outer skin 21, The difference is that the ends are in elastic contact with a predetermined elastic contact force. Regarding the thickness of each part of the tube C ₂ , the thickness of the center part of the grounding part 1 ′ is the largest, and the thickness gradually decreases toward the end part of each side part 2 ′. The thickness is the minimum, and the change in thickness in cross-sectional view is the same as that of the tube C ₁ .

As described above, the tube C ₂ is incorporated in the tire outer skin 21, and the end portions of the side surface portions 2 ′ are in elastic contact with each other. As a result, the ring shape is continuous over the entire circumference in a sectional view. Therefore, the side portions 2 'that becomes the main cause of the ends of elastic contact with each other, with the side surface strength of the tire T ₁ is is increased, by the elastic contact, the tube C ₂ each side surface portion 2' of the also it eliminates the wrinkles on the end portion, also in this regard, has a secondary cause of increasing the side surface strength as the tire T _1. Further, regarding the cushioning property as the tire T ₁ , the end portions of the side surface portions 2 ′ are elastically contacted to form a ring shape in a cross-sectional view and can be deformed as a whole. Note that the tube C ₂ is ring-shaped in a cross-sectional view in the state where it is incorporated in the tire outer skin 21, so that the thickness of the center portion of the ground contact portion 1 ′ is maximum and toward the end portion of each side surface portion 2 ′. With regard to the change in thickness such that the thickness gradually decreases, even if the degree of the change is small (even if the difference in thickness between the center portion of the ground contact portion 1 ′ and the end portions of the side surface portions 2 ′ is small). ), The lateral strength and cushioning properties of the tire T ₁ can be ensured.

For this reason, the tire T ₁ using the tube C ₂ has a structure that secures side strength and cushioning properties by the combined use of the elastic deformation in the sectional view of the tube C ₂ and the hardness of the material. can be secured a large proportion of the hollow portion 4 of the tube C ₂ ', it is possible to increase the porosity of the tube C _2, it is possible weight reduction of the tube.

Further, the tube C ₃ shown in FIG. 9 has a ring shape with a uniform thickness over the entire circumference in a sectional view. Thus, when fitted to the tire outer skin 21 is ring-shaped in cross section is brought slightly changed, different from the tube C _2, the whole is not an integral, bullet in cross section The side load resistance and cushioning properties of the tire T ₁ are increased as much as there is no contact portion. In a cross-sectional view, each portion of the tube C ₂ is connected to the grounding portion 11 corresponding to the grounding portion of the tire outer skin 21, and the side surface portions 12 connected to both sides of the grounding portion 11 and arranged on the side surface of the tire outer skin 21. And it functions as the connection part 13 which is arrange | positioned at opening of the tire outer_layer | skin 21 and connects each said side part 12. Since the tube C ₃ has a structure that secures the lateral strength and the cushioning property by the combined use of the elastic deformation in the cross-sectional view and the hardness of the material, the ratio of the hollow portion 5 of the tube C ₂ can be increased. Since the porosity can be increased, the weight of the tube can be reduced. Since the tube C ₃ has no directionality in the cross-sectional view, there is an advantage that the tube C ₃ can be easily fitted because it is not necessary to consider the directionality in the cross-sectional view of the tube C ₃ when fitting into the tire outer skin 21. . In FIG. 9, A indicates the center of the tube C ₃ in a sectional view.

The tube C ₄ shown in FIG. 10 has a shape in which the center A ₂ of the hollow portion 5 ′ is eccentric with respect to the entire center A ₁ in a sectional view of the tube C ₃ , and has the largest wall thickness. Becomes a grounding portion 11 ′, both sides of the grounding portion 11 ′ become side surface portions 12 ′, and the portions connecting the side surface portions 12 ′ are arranged in the opening of the tire outer skin 21, and the side surface portions 12 ′ are connected to each other. It becomes the connection part 13 'to connect. Thus, since the tube C ₄ has directionality in a cross-sectional view, the positioning protrusion 14 is formed along the longitudinal direction on the outer peripheral surface of the thinnest portion of the connecting portion 13 ′. When the tube C ₄ is incorporated into the tire outer skin 21, the positioning protrusion 14 is arranged at the opening of the tire outer skin 21. This positioning protrusion 14 can be easily formed by forming a recess on the die 31 of the extrusion molding machine 30.

In this way, the tube C ₄ has the thickened portion as the grounding portion 11 ′, and the side surface portions 12 ′ on both sides of the grounding portion 11 ′ gradually decrease in thickness toward the opening of the tire skin 21. Thus, even if it is a ring shape in a cross-sectional view, there is an advantage that a lateral proof stress higher than that of the tube C ₃ can be obtained as much as a thickness change can be imparted along the circumferential direction in the cross-sectional view.

Further, in the tubes C ₁ and C ₂ , the center portion of the grounding portions 1 and 1 ′ is directed toward the end portions of the side surface portions 2 and 2 ′. In the tube C ₄ , the connecting portion 13 is formed from the center portion of the grounding portion 11 ′. The thickness of the tubes C ₁ , C ₂ , and C ₄ is gradually reduced toward the point ', but this degree of reduction is optimal as a tire when appropriately changed in relation to the hardness of the material. Side strength ”and“ cushioning ”can be obtained.

Furthermore, regarding the thickness of each part in the cross-sectional view of the tube, on the condition that the above-mentioned “side strength” and “cushion property” can be ensured, the cross section is substantially U-shaped. In the case of a tube, the wall thickness can be gradually reduced from the center part of the grounding part toward both ends, and in the case of a hollow pipe-like tube, the wall thickness can be gradually reduced from the center part of the grounding part toward the center part of the connecting part. . A tire using this tube has a softer “riding comfort” than the tubes C ₁ , C ₂ and C ₄ .

FIG. 11 is a sectional view of a tire T _{2 for} a senior car. Tire T ₂ of the mobility scooter, compared to the tire T ₁ of the bicycle, and is much smaller overall diameter, yet the cross section of the size of the tire T ₂ of the mobility scooter is large compared to the tire T ₁ of the bicycle for the shape retention of the tire outer skin 51 itself has a characteristic of a much larger compared to the shape retention bicycle tire T ₁ of the tire outer skin 21. The tube C ₁₁ used for the tire T ₂ of the senior car is provided with the above-described characteristics so that each side portion 42 on both sides of the ground contact portion 41 has a substantially U-shaped cross section when fitted into the tire outer skin 51. The tube according to the present invention is suitable for a tire of a senior car, since the lateral strength as the tire T ₂ can be maintained even if the opening between the _two is large. In FIG. 11, reference numeral 52 denotes a rim having a split structure.

Next, with reference to FIG. 12, the relationship between the change of the thickness in the cross-sectional view of the tube of a bicycle and various characteristics of a tube is considered. In FIG. 12, X ₁ , X ₂ , and X ₃ are each an open-type tube in which openings are formed at both ends of each side surface portion in a state of being fitted into the tire outer skin, This is as shown in the figure. On the other hand, Y ₁ , Y ₂ , and Y ₃ are contact-type tubes that are in contact with both ends of each side surface portion in a state of being fitted into the tire skin, and the change in wall thickness in a sectional view is as shown in the figure. It is.

In both the opening type and the contact type tubes, in the tubes X ₂ and Y ₂ that are gradually thinned from the grounding portion toward both ends, the shock absorption mode that is the basis of the cushioning property is the side surface portion. In the tubes X ₃ and Y ₃ which are gradually thinned from the grounding portion toward both ends, the deflection of the grounding portion is subordinate, and the shock absorption mode is On the contrary, the deflection of the grounding portion is the main, the deflection of the side portion is the subordinate, and the shock absorption mode of the tubes X ₁ and Y _{1 in which} the thickness of each portion in the sectional view is constant is both It is the middle of the two types of tubes described above.

From the above-described aspect of shock absorption, the opening type tube X ₂ and the contact type tubes Y ₁ , Y ₂ , Y ₃ are all formed as tire tubes because sufficient lateral strength is obtained. Since the mold tube X ₃ cannot secure the lateral strength, it cannot be used as a tire tube (cannot be used), and it can be seen that the lateral strength of the open-type tube X ₁ is insufficient to be established as a tire tube. . The open tube X ₂ and the contact tube Y ₂ are both characterized by having a “harder ride comfort”, whereas the open tube X ₃ and the contact tube Y ₃ are , Both are characterized by having "soft ride comfort". The open tube X ₁ and the contact tube Y ₁ have the above-mentioned “riding comfort” in the middle.

  From the above, it is desirable to determine the cross-sectional shape of the tube according to the use of the tube.

The tubes C _{1 to} C ₄ and C ₁₁ described above are slightly longer than the circumferential length of the center K of the annular space 22 of the tire skin 21 and are fitted into the annular space 22. Because of the slight “weight allowance” along the circumferential direction, both ends of the tubes C _{1 to} C ₄ and C ₁₁ that are deformed into an annular shape and fitted into the annular space 22 of the tire outer skin 21 Are elastically deformed with each other. Therefore, since both end faces of the tubes C _{1 to} C ₄ and C ₁₁ are pressed against each other in the opposite directions by the elastic restoring force, both ends in the circumferential direction of the tubes C _{1 to} C ₄ and C ₁₁ are brought into contact with each other. The shape retaining force of the portion is high, and the end faces of the tubes C _{1 to} C ₄ and C ₁₁ do not deviate from each other in the cross-sectional view of the butted portion.

In the present invention, in addition to the above-described butted structure on both end faces of the tube, when the both ends in the circumferential direction of the tube are connected to each other by the connecting core members E _{1 to} E ₃ , the above-described butted structure on both end faces of the tube It will be certain.

13A to 13C show the connecting core materials E _{1 to} E ₃ . The connecting core materials E ₁ and E ₂ are used for the hollow pipe-shaped tube C ₃ , and the connecting core material E ₃ is used for the tube C ₁ having a substantially U-shaped cross section. . Each of the connecting cores E _{1 to} E ₃ is formed of a thermoplastic elastomer having a hardness (Shore A hardness 10 to 20) smaller than the hardness of the elastomer that is the material of the tubes C ₁ and C _3. There is no limit, but if it is too short, the function of connecting the ends of the tubes C ₁ and C _{3 in} the circumferential direction will be reduced. If it is too long, the material will be wasted and the connecting operation will be troublesome. From these viewpoints, about 30 to 50 mm is desirable. Since the connecting core material E ₁ has a hollow short pipe shape, the E ₂ has a star shape in cross section, and the E ₃ has a solid short shaft shape, the three types of connecting core materials E _{1 to} E _{3 are used.} Among them, the hollow short pipe-shaped connecting core material E ₁ needs to have the highest hardness within the above-mentioned hardness range, and the solid short shaft-shaped connecting core material E ₃ may have the lowest hardness. The connecting core material E ₂ having a star-shaped cross section has an intermediate hardness. Each coupling core E ₁ to E ₃ is prevented flange portion 61, 62 and 63 shift in the center of the longitudinal direction are formed respectively. With respect to the connecting core material E ₂ having a star-shaped cross section, the shift prevention collar 62 is intermittently provided in the circumferential direction only in the portion corresponding to the top portion 72, and the shift prevention is provided in the portion corresponding to the valley portion. The collar portion 62 is not provided.

Referring to FIGS. 14 to 16, by connecting the both end portions in the circumferential direction of the tube C ₃ by a connecting core E ₁ of the hollow short pipe shape, it will be described fitting to the annular space 22 of the tire outer skin 21 . First, the long tube material in the shape of a hollow pipe is cut into a length (L) slightly longer than the circumferential length of the center K of the annular space 22 of the tire outer skin 21 to form a tube C ₃ , and the tube C ₃ is bent in a ring shape, and the respective portions divided in the longitudinal direction by the shift preventing collar 61 in the connecting core member E ₁ are compressed and fitted into the hollow portions at both ends in the circumferential direction. Then, the both ends of the tube C ₃ bent in an annular shape through the connection core material E ₁ are connected to hold the annular shape. In this state, when the annular tube C ₃ is fitted into the annular space 22 of the tire outer skin 21, as shown in FIGS. 15 and 16, the connecting core material E ₁ is compressed in a cross-sectional view, and the tube C ₃ is compressed both in the circumferential direction (longitudinal sectional view) and in the transverse sectional view, and exerts forces in opposite directions on the respective butting surfaces 3 which are both end surfaces of the tube C _3. It is integrated. On the other hand, the connecting core material E ₁ is compressed by the cross-sectional view, so that it extends along the longitudinal direction by the amount corresponding to the compression in the cross-sectional view. In this manner, the annular tubes C ₃ fitted in the annular space 22 of the tire outer skin 21 are connected to each other via both ends of the circumferential direction in a state of being connected to each other via the compression-connected connecting core material E ₁ ′. The butting surfaces 3 are integrated by applying forces in opposite directions to each other. Note that when the tube C ₁ is fitted into the annular space 22 of the tire outer skin 21, both the tube C ₁ and the connection core material E ₁ are compressed and deformed in a cross-sectional view, but the hardness of the connection core material E ₁ is lower than the hardness of the tube C _1, towards the connecting core E ₁ is larger compression amount than tube C _1.

For this reason, the shape holding force of the both ends in the circumferential direction of the annular tube C ₃ is equivalent to that of the other portions. For example, when the tube C ₃ is used for a bicycle tire, the ride comfort is improved. in the surface, so as not to recognize the presence of each abutment surface 3 of the annular tube C _3, the circumferential opposite end portions of the annular tube C ₃ are integrated.

Further, as shown in FIG. 15, the shift prevention collar 61 at the center in the longitudinal direction of the connecting core E ₁ is sandwiched between the butted surfaces 3 which are both end surfaces of the annular tube C ₃ . While being compressed the compression collar portion 61 'along the thickness direction, the outer peripheral side which does not sandwich the displacement prevention flange portions 61 of each abutment surface 3 of the annular tube C ₃ is directly adhered to the butt It has been. As the shift preventing collar 61 of the connecting core E ₁ is sandwiched between both end faces of the tube C ₃ , the connecting core E ₁ is not displaced with respect to the tube C ₃ even after aged use. The shape retention force at both ends in the circumferential direction ₃ is maintained as it is.

The connecting core material E ₁ is in the form of a hollow short pipe, and the hollow portion 71 communicates the portions on both sides of the connecting core material E ₁ in the hollow portion of the tube C ₃ with each other. Despite the fact that both ends of the tube C ₃ are connected via the material E ₁ , the cushioning properties as the tube or the tire are maintained without being disturbed.

Moreover, FIG. 17 is a cross-sectional view of both end connecting portions in the circumferential direction of the tube C ₃ through the connecting core material E ₂ having a star-shaped cross section instead of the connecting core material E ₁ described above. By inserting and compressing the portions on both sides of the shift preventing collar 62 in the connecting core material E ₂ into the hollow portions at both ends in the circumferential direction of the tube C ₃ , the connecting core material E ₂ ′ is compressed via the connecting core material E ₂ ′. both end portions in the circumferential direction of the tube C ₃ is coupled Te. Since the connecting core E ₂ has the above-described shape, the top 72 is crushed and compressed and deformed, and the compressed and deformed top 72 ′ is in close contact with the inner peripheral surface of the tube C ₃ and is compressed and deformed. The hollow portion 73 remains between the top portions 72 '. The hollow part 73 is in communication with each other on both sides of the connecting core material E ₂ ′ in the hollow part of the tube C ₃ . Only the displacement prevention flange portions provided portion corresponding to the top portion 72 of the connecting core material E ₂ 62 is sandwiched between the respective abutting surface 3 of tube C _3, the displacement of the coupling core member E ₂ with respect to the tube C ₃ Is prevented.

FIG. 18 is a cross-sectional view showing a state in which both ends in the circumferential direction of the tube C ₁ having a substantially U-shaped cross section are connected by a connecting core material E ₂ having a star-shaped cross section. Since the tube C ₁ is partially open in the circumferential direction in a cross-sectional view, it is possible to use a solid short shaft-shaped connecting core material E ₂ , and through a compressed and deformed connecting core material E ₃ ′. both end portions of the circumferential tube C ₁ is coupled Te. The other functions of the connecting core material E ₃ are equivalent to the functions of the connecting core materials E ₁ and E ₂ described above.

C ₀ : Long tube material C _{1 to} C ₄ , C ₁₁ : Tire tube
E _{1 to} E ₃ : Connection core material
F ₁ : Elastic restoring force of the side part of the tube
F ₂ : Pressing force on both ends of the tube
K: Center of the annular space
L: Length of tire tube
T ₁ , T ₂ : Tires 1, 1 ′, 11, 11 ′: Tube grounding portions 2, 2 ′, 12, 12 ′: Tube side portions
3: Butt face of tube
4, 4 ': Hollow portion of tube with non-ring-shaped cross section
5, 5 ': Hollow section of tube having a ring-shaped cross section
13, 13 ': Connecting section of tube having a ring-shaped cross section
14: Positioning protrusion of tube having a ring-shaped cross section
21: Tire hull
22: Annular space of tire skin
23: Rim
61-63: Shift prevention collar

Claims (11)

A tube that is detachably attached to an annular rim and is fitted in the annular space of the annular tire shell while being deformed in a cross-sectional view while remaining straight.
The tube is formed from an elastomer, has side surfaces connected to both sides of the grounding portion in a cross-sectional view, and has a substantially U-shape opened between the side surfaces, It is formed in a straight shape so as to have a length slightly longer than the circumferential length of the center of the space part,
The tube is kept in a straight shape in the annular space of the tire skin, and is placed in the original shape so that the opening side faces the rim. In this state, both end surfaces in the longitudinal direction of the tube are pressed against each other in the opposite direction and are abutted against each other.   The no-puncture tube according to claim 1, wherein an opening of the hollow portion of the tube is narrowed and remains in a state where the tube is fitted in the annular space portion.   2. The no-puncture tube according to claim 1, wherein in a state where the tube is fitted in the annular space portion, end portions of the side surface portions of the tube are in contact with each other in a cross-sectional view.   The no-puncture tube according to any one of claims 1 to 3, wherein the tube is gradually reduced in thickness from the center of the grounding portion toward both ends in a cross-sectional view. A tube that is detachably attached to an annular rim and is fitted in the annular space of the annular tire shell while being deformed in a cross-sectional view while remaining straight.
The tube has a hollow pipe shape,
The tube is formed from an elastomer and is formed in a straight shape so as to have a length slightly longer than the circumferential length of the center of the annular space portion of the tire outer skin,
In the state where each tube is elastically deformed and fitted in the annular space portion of the tire skin while being elastically deformed and fitted in each side portion in a cross-sectional view, both end surfaces in the longitudinal direction of the tube press against each other. No puncture tube characterized by being abutted against each other.   The tube has a ring-shaped cross section, the center of the hollow part is eccentric with respect to the center of the solid part, and the thickness changes over the entire circumference, the largest thickness part. 6. The no-puncture tube according to claim 5, wherein is a grounding portion disposed at a grounding portion of the tire skin.   The positioning protrusion which performs the positioning of the circumferential direction at the time of fitting to a tire outer skin is formed in the part facing the grounding part in the outer peripheral surface of the said tube continuously in a longitudinal direction. No puncture tube as described in.   A connecting core material made of an elastomer having a hardness smaller than the hardness of the tube is fitted into each hollow portion at both ends in the circumferential direction of the tube, and both end surfaces in the circumferential direction of the tube are at both ends of the tube. The no-puncture tube according to any one of claims 1 to 7, wherein are connected to each other in a state of being connected to each other via the connecting core member.   The shift prevention collar part which prevents that the said connection core material slip | deviates along the circumferential direction of the said tube is integrally formed in the center part of the longitudinal direction of the said connection core material. No puncture tube as described in.   The no-puncture tube according to any one of claims 1 to 9, wherein the elastomer is a thermoplastic elastomer.   The no-puncture tube according to any one of claims 1 to 10, wherein the elastomer has a Shore A hardness of 40 to 90.

Images