This application is based upon and claims the benefit of priority of the Japanese Patent Application No. 2013-187230, filed on Sep. 10, 2013, the entire contents of which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to a resin hose and a method for manufacturing the same.
2. Description of the Related Art
In an automobile, fuel fed from a fuel feeding port passes through a filler hose to be stored in a fuel tank. The filler hose is required to smoothly flow the fuel. Thus, for example, JP 2003-182385 A discloses a filler hose in which fuel is straightened and smoothly flows by a portion having a reduced cross-section area of a flow passage in a radial direction. In addition, JP 2010-137591 A discloses a filler hose in which a belt-shaped guide surface is formed.
Further, a resin hose having a non-circular cross-section shape is each disclosed in JP 2001-165383 A, JP 2004-351658 A, and JP 10-257634 A. In addition, a resin composite hose having a non-circular cross-section shape is disclosed in JP
However, as in JP 2003-182385 A, when the cross-section area in the radial direction is reduced in the hose through which liquid such as fuel flows, since the flow rate of fluid flowing through the reduced cross-section area portion is small compared to other portions, the flow rate of fluid flowing through the entire hose becomes smaller.
In addition, particularly in an automobile, it is not easy to wire a fuel hose of a circular cross-section shape concerning placement of other parts. Therefore, the cross-section shape of the fuel hose is required to be, for example, a flat shape according to the portion to be placed. That is, it is required to sufficiently ensure the flow rate of fluid flowing through the resin hose while ensuring flexibility of wiring.
Further, in the case of molding a resin hose into a flat shape, for example, there are a method of molding a material of a circular cross-section shape by press forming, a method of forming an inner peripheral surface shape of a mold for molding a molten resin into a flat shape in advance, and a method of forming a shape of a mandrel for inserting a resin hose into a flat shape. However, even when any of these methods is used, there is a limit to a flattening ratio to be obtained. The flexibility of wiring is improved by obtaining a shape having a higher flattening ratio. Therefore, it is required to obtain a resin hose of a shape having a high flattening ratio.
The invention is achieved in consideration of the above circumstances, and a first object is to sufficiently ensure the flow rate of fluid flowing through a resin hose while ensuring flexibility of wiring. A second object is to manufacture a resin hose of a shape having a high flattening ratio.
(Resin Hose)
The resin hose according to an aspect of the invention comprises: a round portion having a round flow-passage; and a flat portion that includes a flat flow-passage and has a flow-passage cross-section area equal to or larger than a flow-passage cross-section area of a minimum inner diameter portion in the round portion, a short width of the flat flow-passage being smaller than an inner diameter of the minimum inner diameter portion and a long width of the flat flow-passage being larger than the inner diameter of the minimum inner diameter portion.
When the resin hose has the flat portion, flexibility of wiring of the resin hose is improved. Here, even though the resin hose has the flat portion, since the flow-passage cross-section area of the flat portion is equal to or larger than the flow-passage cross-section area of the minimum inner diameter portion in the round portion, it is possible to ensure that the flow rate of fluid flowing through the flat portion is equal to or more than the flow rate in the minimum round portion. As a result, the flow rate of fluid flowing through the resin hose totally increases.
Preferably, the flat portion may be manufactured using: a resin melting and molding process of molding an intermediate flat portion of an intermediate molded body, the intermediate flat portion having a flow-passage cross-section area larger than the flow-passage cross-section area of the flat portion, by introducing a molten resin into a metal mold having a flat-shaped inner peripheral surface and then solidifying the molten resin; and a press forming process of forming the flat portion by press forming the intermediate flat portion of the intermediate molded body to further reduce a short width of the intermediate flat portion in the intermediate molded body.
Here, the process of introducing the molten resin into the metal mold having the flat-shaped inner peripheral surface and subsequently solidifying the molten resin in the resin melting and molding process is called “resin melting and molding”. That is, in the resin melting and molding process, the intermediate flat portion of the intermediate molded body is formed by the resin melting and molding, and then the flat portion as a final shape is formed by press forming the intermediate flat portion of the intermediate molded body. Accordingly, the flat portion is not molded by a single molding process but is formed by two times of forming processes. As a result, it is possible to form the resin hose of the shape having the high flattening ratio.
If the flat portion is formed by press forming the cylindrical-shaped intermediate molded body, positioning of the cylindrical-shaped intermediate molded body is not easy, and the phase of the flat portion is likely to be deviated from a desired phase. In contrast, according to the above process, since the press forming is performed on the intermediate flat portion of the previously molded intermediate molded body, a flat direction easily coincides with the short width direction of the intermediate flat portion. Accordingly, the phase of the finally shaped flat portion can easily become the desired phase.
In addition, if the flat portion having a small short-width is molded only by the resin melting and molding, the flat-shaped inner peripheral surface of the metal mold is required to be formed into a shape having the small short-width as in the flat portion. Then, since the size of a nozzle for injecting the molten resin into the metal mold is restricted by the size of the inner peripheral surface of the metal mold, the diameter of the nozzle has to become small. When the diameter of the nozzle becomes small, the pressure of the molten resin injected from the nozzle is raised and productivity decreases. In contrast, according to the resin melting and molding process of the above aspect of the invention, the short width of the intermediate flat portion of the intermediate molded body is larger than the short width of the finally shaped flat portion. Accordingly, it is possible to improve the productivity.
In addition, preferably, the short width of the flat flow-passage of the intermediate flat portion in the intermediate molded body is equal to or larger than the inner diameter of the round portion, and the long width of the flat flow-passage of the intermediate flat portion in the intermediate molded body is larger than the inner diameter of the round portion.
Therefore, it is possible to sufficiently increase the size of the nozzle for injecting the molten resin into the metal mold in the resin melting and molding process. As a result, it is possible to reduce the pressure of the molten resin injected from the nozzle into the metal mold. Therefore, it is possible to provide higher productivity.
In addition, preferably, the flat portion is formed by press forming the intermediate flat portion in a state where a mandrel having a diameter equal to or smaller than the short width of the flat flow-passage in the flat portion is inserted into the intermediate molded body, in the press forming process.
Since the press forming is performed in the state where the mandrel is inserted into the intermediate molded body, a deformation amount due to the press forming is regulated by the mandrel. Accordingly, it is possible to easily form the flat portion of the desired shape. Moreover, the diameter of the mandrel is equal to or shorter than the short width of the flat flow-passage in the flat portion. That is, in the case of performing the press forming, the gap remains formed in the direction of the long width of the flat portion. Even though the gap exists, since the intermediate flat portion of the intermediate molded body is previously molded, it is possible to form the desired flat portion. Further, it is possible to easily insert the mandrel into the intermediate molded body by forming the diameter of the mandrel to be equal to or shorter than the short width of the flat flow-passage in the flat portion.
In addition, preferably, the resin hose comprises a straight pipe portion and a bent portion formed by at least a part of the intermediate flat portion, the intermediate molded body is molded into a straight pipe shape, and the flat portion is formed in the resin hose and the bent portion is also formed such that both sides in the direction of the short width of the intermediate flat portion become an outer bent side and an inner bent side of the bent portion, by press forming on the intermediate molded body having the straight pipe shape in the press forming process.
When the bent portion is formed by the press forming, wrinkles are less likely to occur in the bent portion by configuring such that at least a part of the bent portion includes the previously molded intermediate flat portion and both sides in the direction of the short width become the outer bent side and the inner bent side of the bent portion.
In addition, preferably, the minimum inner diameter portion of the round portion is disposed at both ends of the flat portion in a flow direction.
The long width of the flat portion is larger than the inner diameter of the minimum inner diameter portion of the round portion. For this reason, in the resin hose provided with the round portion having the minimum inner diameter at both ends of the flat portion, since the mandrel is formed into an undercut shape when the forming is performed by the mandrel, it is difficult to perform the forming with the mandrel. However, even in the resin hose having such a shape, it is possible to reliably perform the forming without depending on the shape of the mandrel by applying the above aspect of the invention.
(Method for Manufacturing Resin Hose)
A method for manufacturing a resin hose according to another aspect of the invention is a method for manufacturing a resin hose with a flat portion and includes: a resin melting and molding process of molding an intermediate flat portion of an intermediate molded body by introducing a molten resin into a metal mold having a flat-shaped inner peripheral surface and then solidifying the molten resin; and a press forming process of forming the flat portion having a flow-passage cross-section area smaller than a flow-passage cross-section area of the intermediate flat portion of the intermediate molded body by press forming the intermediate flat portion of the intermediate molded body to further reduce a short width of the intermediate flat portion in the intermediate molded body.
That is, in the manufacturing method according to the above aspect of the invention, the intermediate flat portion of the intermediate molded body is formed by the resin melting and molding, and then the flat portion as a final shape is formed by performing the press forming the intermediate flat portion of the intermediate molded body. Accordingly, the flat portion is not molded by a single molding process but is formed by two times of forming processes. As a result, it is possible to form the resin hose of the shape having a high flattening ratio. Moreover, according to the above aspect of the invention, the phase of the flat portion can easily become the desired phase and the productivity can be improved.
The resin hose 10 according to the first embodiment will be described with reference to
The resin hose 10 is formed of one or more kinds of resin layers. As one of resin materials for forming the resin hose 10 adapted to the filler hose, for example, high density polyethylene (HDPE) having excellent fuel oil resistance is preferable.
Here, the resin hose 10 is wired between the fuel feeding port and the fuel tank 30, but other parts constituting the automobile are present in such a region. For this reason, as illustrated in
The fuel feeding cap 20 is mounted to the one-end round portion 11 of the resin hose 10. The other-end round portion 16 of the resin hose 10 is attached to the fuel tank 30. As illustrated in
As illustrated in
As illustrated in
The bent portion 12 of the resin hose 10 is formed into a non-bellows-like tubular shape, and at least a part of the flat straight-pipe portion 13 has a flat tubular shape at the bent portion 12. Accordingly, the bent portion 12 has a shape with no flexibility in shape deformation. On the other hand, the bellows-like bent portion 15 of the resin hose 10 is formed into a bellows-like tubular shape. Therefore, the bellows-like bent portion 15 has a shape with the flexibility in shape deformation.
Here, the relation between the inner diameters Da and Dc of the minimum inner diameter portion of the round flow-passage in the round portions 11, 14, and 16 and the long width Db1 and the short width Db2 of the flat flow-passage of the flat straight-pipe portion 13 is indicated in Formula (1). That is, the long width Db1 of the flat flow-passage is larger than the inner diameters Da and Dc of the minimum inner diameter portion in the round portions 11, 14, and 16, and the short width Db2 of the flat flow-passage is smaller than the inner diameters Da and Dc of the minimum inner diameter portion.
[Formula 1]
Db1>Da=Dc>Db2 (1)
In addition, assumed that a flow-passage cross-section area of the minimum inner diameter portion in the round portion 11 is Sa, a flat flow-passage cross-section area of the flat straight-pipe portion 13 is Sb, and a flow-passage cross-section area of the minimum inner diameter portion in the round portions 14 and 16 is Sc, the relation of Formula (2) is satisfied. That is, the flow-passage cross-section area Sb of the flat straight-pipe portion 13 is equal to or larger than the flow-passage cross-section areas Sa and Sc of the minimum inner diameter portion in the round portions 11, 14, and 16.
[Formula 2]
Sb≧Sa=Sc (2)
As described above, since the resin hose 10 has the flat straight-pipe portion 13, flexibility of wiring of the resin hose 10 is improved. In addition, since the resin hose 10 also has the bellows-like bent portion 15, the flexibility of wiring of the resin hose 10 is improved.
Here, the flow-passage cross-section area Sb of the flat straight-pipe portion 13 is larger than the flow-passage cross-section areas Sa and Sc of the minimum inner diameter portion in the round portions 11, 14, and 16. For this reason, it is possible to ensure that the flow rate of fluid flowing through the flat straight-pipe portion 13 is equal to or more than the flow rate in the minimum round portion of the round portions 11, 14, and 16. As a result, the flow rate of the fluid flowing through the resin hose 10 totally increases.
(2.1. Overview of all Processes in Method for Manufacturing Resin Hose 10)
Next, a method for manufacturing the above-described resin hose 10 will be described with reference to
First, the overview of the method for manufacturing the resin hose 10 will be described with reference to
Subsequently, the worker inserts a mandrel 60, which has a circular cross-section shape and is formed by, for example, a flexible resin material or metal spring, into the intermediate molded body 50 (S2). That is, the mandrel 60 is bendable but is formed so as to maintain the cross-section shape in the radial direction. The outer diameter of the mandrel 60 is sized to coincide with the short width Db2 of the flat straight-pipe portion 13 of the resin hose 10. Further, the mandrel 60 may have an angular cross-section shape such as a rectangular cross-section shape other than the circular cross-section shape. For example, a width between opposite surfaces in the mandrel 60 having the rectangular cross-section is sized to coincide with the short width Db2 of the flat straight-pipe portion 13.
Subsequently, after the intermediate molded body 50 is heated to be softened (S3), the flat straight-pipe portion 13 and the bent portion 12 are formed by the press forming (S4: press forming process). The flat straight-pipe portion 13 is formed by further increasing the flattening ratio of the intermediate flat portion 52 (illustrated in
(2.2. Details of Resin Melting and Molding Process)
Next, details of the resin melting and molding process S1 in
As illustrated in
Simultaneously, gas pressure is applied from the inside of the nozzle 111. Accordingly, the molten resin material is pressed against the inner peripheries of the metal mold rows 121 and 122, and thus the molten resin of the cylindrical shape is molded depending on an inner peripheral surface shape of each metal mold.
Then, after the molten resin is introduced into the metal mold rows 121 and 122, the introduced resin is cooled when passing through the inside of the metal mold rows 121 and 122, and thus the molded molten resin is solidified. In this way, the intermediate molded body 50 is molded.
The intermediate molded body 50 has shapes illustrated in
The round portions 51, 53, and 55 of the intermediate molded body 50 have a round flow-passage, that is, a round cross-section shape in the radial direction, respectively. Inner diameters of the minimum inner diameter portions in the round portions 51, 53, and 55 are defined by Da and Dc as illustrated in
As illustrated in
Here, in the intermediate molded body 50, the relation between the inner diameters Da and Dc (equal to Da and Dc in
[Formula 3]
Db3>Da=Dc≈Db4 (3)
In addition, the relation between the long width Db3 and short width Db4 in the intermediate flat portion 52 of the intermediate molded body 50 and the long width Db1 and short width Db2 in the flat straight-pipe portion 13 of the finally formed resin hose 10 is indicated in Formula (4). That is, the flattening ratio of the intermediate flat portion 52 of the intermediate molded body 50 is smaller than the flattening ratio of the flat straight-pipe portion 13 of the finally formed resin hose 10.
[Formula 4]
Db1>Db3>Db4>Db2 (4)
In the intermediate molded body 50, assumed that a flow-passage cross-section area of the minimum inner diameter portion of the round portion 51 is Sa2, a flow-passage cross-section area of the intermediate flat portion 52 is Sb2, and a flow-passage cross-section area of the minimum inner diameter portion of the round portion 53 and 55 is Sc2, the relation of Formula (5) is derived from the relation of Formula (3). That is, the flow-passage cross-section area Sb2 of the intermediate flat portion 52 has a cross-section area larger than the flow-passage cross-section areas Sa2 and Sc2 of the minimum inner diameter portion of the round portions 51, 53, and 55.
[Formula 5]
Sb2>Sa2=Sc2 (5)
Further, as indicated in Formula (6), the flow-passage cross-section area Sb2 of the intermediate flat portion 52 of the intermediate molded body 50 is larger than the flow-passage cross-section area Sb of the flat straight-pipe portion 13 of the finally formed resin hose 10.
[Formula 6]
Sb2>Sb (6)
(2.3. Details of Press Forming Process)
Next, details of a press forming process S4 in
In the press forming process, further, the flat straight-pipe portion 13 of the resin hose 10 is formed by increasing the flattening ratio of the intermediate flat portion 52 of the intermediate molded body 50. That is, the flat straight-pipe portion 13 of the resin hose 10 is formed by further reducing the short width Db4 of the intermediate flat portion 52 of the intermediate molded body 50 and by increasing the long width Db3.
Specifically, metal molds 210 and 220 are used in the press forming process. As illustrated in
Then, as illustrated in
The flow-passage cross-section area Sb of the flat straight-pipe portion 13 of the resin hose 10 is equal to or larger than the minimum flow-passage cross-section areas Sa and Sc of the round portions 11, 14, and 16. Accordingly, it is possible to ensure that the flow rate of fluid flowing through the flat straight-pipe portion 13 is equal to or more than the flow rate in the minimum round portion of the round portions 11, 14, and 16. As a result, the flow rate of fluid flowing through the resin hose 10 totally increases.
Here, it is assumed that the intermediate flat portion 52 of the intermediate molded body 50 is not the flat shape but a round shape having the same diameter as the minimum inner diameter portion of the round portions 11, 14, and 16. When the flat portion is formed by performing the press forming the round shape portion, the flow-passage cross-section area of the flat portion inevitably becomes smaller than the flow-passage cross-section area of the round portion. That is, when the shape before the press forming is the round shape having the same diameter as in the round portion, it is not possible to obtain a flat portion having an intended flow-passage cross-section area.
In the first embodiment, as described above, the intermediate flat portion 52 having the flow-passage cross-section area larger than that of the round portions 51, 53, and 55 is molded in the resin melting and molding, and the desired flat straight-pipe portion 13 as the final shape is formed by press forming the intermediate flat portion 52. Thus, it is possible to obtain the desired flat straight-pipe portion 13 by combining the resin melting and molding process with the press forming process. Further, since the flat straight-pipe portion 13 is not molded by a single molding process but is formed by two times of forming processes, it is possible to form the resin hose 10 of the shape having the high flattening ratio.
In addition, if the flat straight-pipe portion 13 is formed by press forming the cylindrical-shaped intermediate molded body 50, positioning of the cylindrical-shaped intermediate molded body 50 is not easy, and the phase of the flat straight-pipe portion 13 is likely to be deviated from a desired phase. In contrast, according to the first embodiment, since the press forming is performed on the intermediate flat portion 52 of the previously molded intermediate molded body 50, a flat direction easily coincides with the short width direction of the intermediate flat portion 52. That is, the phase of the finally shaped flat straight-pipe portion 13 can easily become the desired phase.
In addition, if the flat straight-pipe portion 13 having a small short-width is molded only by the resin melting and molding, the flat-shaped inner peripheral surface of the metal mold rows 121 and 122 is required to be formed into a shape having the small short-width as in the flat straight-pipe portion 13. Then, since the size of the nozzle 111 for injecting the molten resin into the metal mold rows 121 and 122 is restricted by the size of the inner peripheral surface of the metal mold rows 121 and 122, the diameter of the nozzle 111 has to become small. When the diameter of the nozzle 111 becomes small, the pressure of the molten resin injected from the nozzle 111 is raised and productivity decreases. In contrast, according to the resin melting and molding process of the first embodiment, the short width of the intermediate flat portion 52 of the intermediate molded body 50 is larger than the short width of the finally shaped flat straight-pipe portion 13. Accordingly, it is possible to improve the productivity.
Particularly, in the first embodiment, the short width Db4 of the flat flow-passage of the intermediate flat portion 52 is equal to or larger than the inner diameters Da and Dc of the round portions 11, 14, and 16, and the long width Db3 of the flat flow-passage of the intermediate flat portion 52 is larger than the inner diameters Da and Dc of the round portions 11, 14, and 16.
Therefore, it is possible to sufficiently increase the size of the nozzle 111 for injecting the molten resin into the metal mold rows 121 and 122 in the resin melting and molding process. As a result, it is possible to sufficiently reduce the pressure of the molten resin injected from the nozzle 111 into the metal mold rows 121 and 122. Therefore, it is possible to provide excellent productivity.
Further, in the press forming process, the press forming is performed on the intermediate flat portion 52 of the intermediate molded body 50 in the state where the mandrel 60 having the diameter equal to or smaller than the short width Db2 of the flat flow-passage in the flat straight-pipe portion 13 is inserted into the intermediate molded body 50, and the flat straight-pipe portion 13 is formed. Accordingly, since the press forming is performed in the state where the mandrel 60 is inserted into the intermediate molded body 50, a deformation amount due to the press is regulated by the mandrel 60.
Specifically, in the case of the mandrel 60 having the circular cross-section, when the short width Db4 of the intermediate flat portion 52 reaches the outer diameter of the mandrel 60, the intermediate flat portion 52 is not deformed any more. Therefore, it is possible to easily form the flat straight-pipe portion 13 having the desired shape. Moreover, the diameter of the mandrel 60 is equal to or shorter than the short width Db2 of the flat flow-passage in the flat straight-pipe portion 13.
That is, in the case of performing the press forming, the gap remains formed in the direction of the long width Db1 of the flat straight-pipe portion 13. Even though the gap exists, since the intermediate flat portion 52 of the intermediate molded body 50 is previously molded, it is possible to form the desired flat straight-pipe portion 13. Further, it is possible to easily insert the mandrel 60 into the intermediate molded body 50 by forming the diameter of the mandrel 60 to be equal to or shorter than the short width Db2 of the flat flow-passage in the flat straight-pipe portion 13.
In addition, the resin hose 10 has the flat straight-pipe portion 13 which is continuous to the bent portion 12. Further, the bent portion 12 of the resin hose 10 includes at least a part of the intermediate flat portion 52. Moreover, the outer bent side and the inner bent side of the bent portion 12 become both sides in the direction of the short width of the intermediate flat portion 52. Therefore, when the bent portion 12 is formed by press forming, wrinkles are less likely to occur in the bent portion 12 by configuring such that at least a part of the bent portion 12 includes the previously molded intermediate flat portion 52 and both sides in the direction of the short width become the outer bent side and the inner bent side.
In addition, the resin hose 10 is provided with one-end round portion 11 including the minimum inner diameter portion at one end of the flat straight-pipe portion 13. the resin hose 10 is provided with the intermediate round portion 14 and the other-end round portion 16 including the minimum inner diameter portion at the other end of the flat straight-pipe portion. The minimum inner diameter portions of the round portions 11, 14, 16 are disposed at both ends of the flat straight-pipe portion 13. That is, the long width Db1 of the flat straight-pipe portion 13 is larger than the inner diameters Da and Dc of the minimum inner diameter portion of the round portions 11, 14, and 16. For this reason, in the resin hose 10 provided with the round portions 11, 14, and 16 having the minimum inner diameter at both ends of the flat straight-pipe portion 13, since the mandrel is formed into an undercut shape when the forming is performed only by the mandrel, it is difficult to perform the forming with the mandrel. However, even in the resin hose 10 having such a shape, it is possible to reliably perform the forming without depending on the shape of the mandrel 60 by applying the manufacturing method according to the first embodiment.
A method for manufacturing a resin hose 10 according to a second embodiment will be described with reference to
As illustrated in
Subsequently, as illustrated in
As illustrated in
Here, the second intermediate molded body 350 is disposed between the metal molds 310 and 320 such that the metal molds 310 and 320 are located in the short width direction of the intermediate flat portion 52. If a portion of the second intermediate molded body 350 disposed between the metal molds 310 and 320 has a cylindrical shape, the phase of the second intermediate molded body 350 is not easily positioned with respect to the metal molds 310 and 320. However, since the intermediate flat portion 52 is previously molded in the second intermediate molded body 350 and the metal molds 310 and 320 are located in the direction of the short width of the intermediate flat portion 52, the second intermediate molded body 350 can be easily and stably disposed between the metal molds 310 and 320. Accordingly, it is possible to form the resin hose 10 having the desired shape.
Further, the example of applying the resin hose 10 to a filler hose of an automobile is described in the above embodiments, but the invention is not limited thereto and any resin hose through which fluid flows is applicable regardless of uses.
Number | Date | Country | Kind |
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2013-187230 | Sep 2013 | JP | national |