JP2006247892A - Joining structure of two members, joining method of them, gas container and its manufacturing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a joining structure of two members capable of properly joining the end parts of a pair of resin members mutually by laser welding in a state that the mutual positional shift of the end parts of the resin members is simply suppressed, a joining method of two members, a gas container and its manufacturing method. <P>SOLUTION: A male screw 21 is provided to the almost cylindrical end part 12 of the resin member 1 and a female screw 41 is provided to the almost cylindrical end part 32 of the resin member 2. The male screw 21 is irradiated with a laser beam in the state threaded with the female screw 41 to form the joining structure of two members of which the end parts 12 and 32 are joined by laser welding. Further, this joining structure is adapted to the resin liner 111 of the gas container 101 to join liner constituent members 121 and 122 mutually in a threaded state by laser welding. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a two-member joining structure and joining method for joining the substantially cylindrical ends of a pair of resin members. The present invention also relates to a gas container in which a resin liner joins a plurality of liner constituent members, and more particularly to a gas container in which an end portion of a liner constituent member is substantially cylindrical and a method for manufacturing the same.

  Conventionally, from the viewpoint of weight reduction or the like, a pipe-shaped product constituting a pipe or the like and an inner shell (liner) of a gas container are made into a resin molded product. This type of resin molded product is often configured by joining divided molded products that have been divided and molded in advance, and a laser welding method is used as a joining method in that case.

For example, Patent Document 1 describes a structure in which ends of a pair of pipe molded products are joined by laser welding. In this joining structure, the tapered joining surface formed on the outer surface of the end of one pipe molded product is brought into contact with the reverse tapered joining surface formed on the inner surface of the end of the other pipe molded product, and in this contact state, the laser is joined. Are bonded to each other by laser welding.
JP 2004-90630 A (FIGS. 1 and 2)

Since such a conventional joining structure has a tapered / inverse tapered joining surface, it is useful in that the joining area can be increased even when joining thin pipe molded products, for example. . However, since the laser irradiation is performed in a state in which both the bonding surfaces are in contact with each other, there is a possibility that the bonding surfaces are not in contact with each other at the time of laser irradiation, which may cause a bonding failure.
Of course, in order to solve this problem of poor bonding, it is conceivable to prepare a pressure jig for maintaining the contact state between the ends, but this is costly and complicated.

  The present invention provides a two-member joining structure and joining method capable of appropriately joining the end portions by laser welding in a state in which positional deviation between the end portions of a pair of resin members is easily suppressed. Is the purpose.

  Moreover, this invention applies this two-member joining structure to the resin liner of a gas container, and joins the edge parts appropriately by laser welding in the state which suppressed the position shift of the edge parts of a liner structural member. It is an object of the present invention to provide a gas container and a manufacturing method thereof.

  The two-member joining structure of the present invention is a two-member joining structure in which a pair of resin members having at least substantially cylindrical end portions are joined by laser welding with their end portions engaged by an engagement structure. The engagement structure includes a male screw provided at an end portion of one resin member and a female screw provided at an end portion of the other resin member and screwed to the male screw.

  According to this configuration, since the screw or the female screw is provided at the substantially cylindrical end portion that becomes the joining portion of each resin member, it is possible to irradiate the laser in a state where they are screwed together. Thereby, since it can hold | maintain so that edge parts may closely_contact | adhere at the time of laser irradiation, the position shift of edge parts can be suppressed suitably, without using a pressurization jig etc. Therefore, the end portions can be favorably bonded by laser welding. Moreover, since the joined portion after laser welding is also joined by screw fastening, the strength of the joined portion can be improved. Furthermore, when joining the substantially cylindrical ends, the centering is usually complicated. However, the centering can be easily performed by the screwed structure of the male screw and the female screw.

  Here, the “resin member having at least a substantially cylindrical end” includes that the resin member as a whole has a shape such as a cylindrical shape, an annular shape, a bowl shape, or a dome shape.

  In the case of the joint structure of the present invention described above, the inner peripheral surface of the end portion provided with the female screw has an inclined joint surface, and the outer peripheral surface of the end portion provided with the male screw is aligned with the joint surface. And it is preferable that it has a joint surface contact | abutted to this and these joint surfaces are joined by laser welding.

  According to this configuration, by configuring the joint surfaces with inclined surfaces, the contact area between the joint surfaces (joint area) can be increased, and the joint surfaces can be useful for alignment between the joint surfaces.

  In this case, it is preferable that the male screw and the female screw are joined together by the laser welding together with the joining surfaces.

  According to this configuration, the joint area can be further increased, and the sealing performance at the joint after laser welding can be enhanced.

  In these cases, it is preferable that the end portion provided with the female screw is formed of a laser-transmitting resin, and the end portion provided with the male screw is formed of a laser-absorbing resin.

  According to this configuration, when the laser is irradiated from the laser-transmitting end portion side, the laser-absorbing end portion is heated and melted, and the laser-transmitting end portion is heated and melted by heat transfer from the end portion. As described above, the end portions can be appropriately joined to each other by providing the end portions with a laser transmitting or absorbing property. In addition, although it is sufficient to give the characteristic with respect to this kind of laser only to an edge part, the direction which gives the whole resin member including an edge part can manufacture a resin member easily.

  In these cases, it is preferable that the male screw and the female screw are made of a metal material.

  According to this configuration, a firm fastening force can be obtained as compared with the case where the male screw and the female screw are formed of resin. The male screw or the female screw may be provided at the end of the resin member by adhesion or the like, or may be provided at the end of the resin member by insert molding on the resin member.

  In these cases, it is preferable that the male screw is a tapered male screw and the female screw is a tapered female screw.

  According to this configuration, since it is a taper screw connection, one screw thread of the taper male screw and the taper female screw is crushed during screwing. Thereby, compared with the case where it connects with a straight screw, the sealing performance in the junction part after laser welding can be improved further.

  The two-member joining method of the present invention is a two-member joining method in which a pair of resin members having at least substantially cylindrical end portions are joined to each other, and at one end of the one resin member. Laser irradiation is performed in a state where the provided male screw and the screw for providing at the end of the other resin member are screwed together, and the ends are joined together by laser welding.

  According to this configuration, since the laser is irradiated in a state where the ends are screwed together, the position deviation between the ends is suitably suppressed without using a pressurizing jig or the like. Good bonding can be achieved. Moreover, the point which can improve the intensity | strength of the junction part after laser welding, and the point which can align center part easily are the same as the above.

  In this case, after screwing the male screw and the female screw until the joint surface of the end portion provided with the male screw comes into contact with the joint surface of the end portion provided with the female screw, the joint surfaces are laser-bonded to each other. It is preferable to join by welding.

  According to this configuration, since the joint surfaces are screwed until they come into contact with each other, the joint surfaces to be laser welded can be reliably brought into close contact with each other. Thereby, the laser welding of the joining surfaces can be performed satisfactorily and reliably.

  In this case, it is preferable to join the joining surfaces to each other by laser welding in the circumferential direction.

  According to this configuration, the entire circumference of the joint surfaces is line welded by the laser.

  In these cases, it is preferable that the male screw and the female screw are joined together by laser welding together with the joining surfaces. Further, the end of one resin member is formed of a laser-transmitting resin, and the end of the other resin member is formed of a laser-absorbing resin, and laser absorption is performed from this laser-transmitting end portion side. It is preferable that the joining surfaces are joined by laser welding by irradiating a laser toward the end of the property. Furthermore, it is preferable that the male screw and the female screw are made of a metal material. Moreover, it is preferable that a male screw consists of a taper male screw, and a female screw consists of a taper female screw.

  The gas container of the present invention uses a resin member as a pair of liner constituent members, the resin liner formed by joining the liner constituent members using the above-described two-member joining method of the present invention, and the outer periphery of the resin liner. And a reinforcing layer disposed on the surface.

  According to this configuration, since the above-described bonding method is used to integrally bond the pair of liner constituent members, a well-bonded resin liner can be configured. Since the gas container is provided with this resin liner, it is possible to improve the gas tightness and productivity of the gas container.

  Another gas container of the present invention is a gas container having a resin liner, and the resin liner is formed by joining a plurality of liner constituent members having at least substantially cylindrical end portions, and joining the liner constituent members to each other. The portion is provided with an engagement structure for engaging the substantially cylindrical ends with each other, and a laser welded portion in which the substantially cylindrical ends are joined by laser welding. It has a male screw provided in one of the parts and a female screw provided in the other of the end parts and screwed into the male screw.

According to this structure, in the manufacturing process of the resin liner which joins liner structural members, the edge parts of a liner structural member can be engaged by an engagement structure, and a laser can be irradiated in this engagement state. Thereby, even if it does not use a pressurization jig | tool etc., the position shift of edge parts can be suppressed suitably, and edge parts can be favorably joined by laser welding. In particular, since the engaging structure is a screwed structure, the end portions can be held in close contact with each other, and centering at the time of joining becomes easy. Further, even after laser welding, since the joint is engaged by the engagement structure in addition to the laser weld, the strength of the joint can be improved.
Here, the laser welding portion refers to a portion formed by melting a part of the end portion of one liner constituent member and a part of the end portion of the other liner constituent member.

  In this case, the inner peripheral surface of the end portion provided with the female screw has an inclined joint surface, and the outer peripheral surface of the end portion provided with the male screw aligns with and contacts the joint surface. It is preferable that the laser weld portion is formed by melting the joint surfaces.

  According to this configuration, the contact area (bonding area) between the bonding surfaces can be increased as described above.

  Further, in the gas container of the present invention, the end portion provided with the female screw is formed of a laser-transmitting resin, and the end portion provided with the male screw is similar to the above-described two-member joint structure. It is preferable to be formed of a laser-absorbing resin. The male screw and the female screw are preferably formed of a metal material. Further, it is preferable that the male screw is a tapered male screw and the female screw is a tapered female screw.

  The method of manufacturing a gas container according to the present invention is a method of manufacturing a gas container having a resin liner formed by joining a plurality of liner constituent members having at least a substantially cylindrical end, and is one liner to be joined to each other. An engagement step of engaging the substantially cylindrical end of the component member with the substantially cylindrical end of the other liner component member, and after the engagement step, laser irradiation is performed and the ends are laser-bonded. An irradiation step for joining by welding, and the engagement step is provided at a substantially cylindrical end portion of one liner constituent member and a substantially cylindrical end portion of the other liner constituent member. Therefore, it is performed by screwing with a screw.

  According to this configuration, since the laser is irradiated in a state in which the ends of the liner constituent members are screwed together, the position shift between the ends is suitably suppressed without using a pressurizing jig or the like. The ends can be joined well. Further, even after laser welding, the strength of the joint can be improved by the amount that the ends are screwed together.

  Moreover, in the manufacturing method of the gas container of the said invention, it is preferable to carry out as follows similarly to the joining method of said 2 member.

  The engagement step is performed by screwing the male screw and the female screw until the joint surface of the end portion provided with the male screw comes into contact with the joint surface of the end portion provided with the female screw, and the irradiation step is performed. This is done by joining the contact surfaces in contact with each other by laser welding. More preferably, this irradiation step is performed by joining the joining surfaces in the circumferential direction by laser welding. Preferably, the irradiation step is performed by joining a screwed male screw and a female screw together with the joining surfaces by laser welding.

  Preferably, prior to the engaging step, the substantially cylindrical end of one liner constituent member to be joined to each other is formed of a laser-transmitting resin, and the substantially cylindrical end of the other liner constituent member Is formed with a laser-absorbing resin, and the irradiation step irradiates the laser from the laser-transmitting end portion side toward the laser-absorbing end portion, and joins the bonding surfaces together by laser welding. Is done. More preferably, the male screw is a tapered male screw, and the female screw is a tapered female screw.

  Preferably, prior to the engaging step, a male screw made of a metal material is provided by insert molding on one liner constituent member to be joined to each other, and an insert molding is performed on the other liner constituent member from the metal material. The method further includes the step of providing a female screw.

  According to this configuration, since the screw and the female screw are made of a metal material in the same manner as described above, in addition to being able to obtain a strong fastening force, insert molding is performed. A female screw can be easily provided.

  According to the two-member joining structure and the joining method of the present invention, the end portions of one resin member and the end portions of the other resin member are easily laser-welded with each other in a state in which misalignment is easily suppressed. Therefore, it can join appropriately.

  According to the gas container and the gas container manufacturing method of the present invention, similarly, when one liner constituent member and another liner constituent member of the resin liner are joined by laser welding, positional deviation between the end portions is suppressed. Since it can do, edge parts can be joined appropriately.

  Preferred embodiments of the present invention will be described below with reference to the accompanying drawings. The characteristic part of this embodiment is that, when two resin members having substantially cylindrical end portions are joined, the end portions are engaged with each other and laser-welded. Hereinafter, in the first and second embodiments, a joining structure of a resin pipe material and a joining method thereof will be described. In the third and fourth embodiments, a gas container in which this joining structure is applied to a resin liner will be described together with a manufacturing method thereof.

<First Embodiment>
As shown in FIGS. 1 and 2, a pipe material 1 made of a laser-absorbing resin and a pipe material 2 made of a laser-transmitting resin are joined to form a single pipe-shaped resin molded product. . Both the pipe materials 1 and 2 are formed in a cylindrical shape with the same outer diameter as a whole, and are joined with their axial directions matched.

  The laser-absorbing pipe material 1 has a trunk portion 11 extending a predetermined length in the axial direction thereof, and a substantially cylindrical joining end portion 12 formed on one end side of the trunk portion 11 that is opened. ing. The outer peripheral surface of the joining end portion 12 is formed on the distal end side, and has a male screw 21 having a smaller diameter than the outer diameter of the trunk portion 11 and a joining surface inclined at a predetermined angle from the proximal end side of the male screw 21 to the trunk portion 11. 22 and a step surface 23 formed between the joint surface 22 and the outer peripheral surface of the body portion 11.

  The male screw 21, the joining surface 22, and the step surface 23 are formed over the circumferential direction of the joining end portion 12. The male screw 21 is formed together with the overall shape of the pipe material 1 when the pipe material 1 is molded using various molding methods such as injection molding. The external thread 21 is a parallel external thread extending a predetermined length in the axial direction. However, by forming the male screw 21 with a tapered male screw, it is possible to improve the tightness resistance at the threaded portion when the pipe members 1, 2 are joined together.

  The joint surface 22 is integrally connected to the base end of the male screw 21 and is formed in a tapered shape. The step surface 23 is composed of an inclined surface slightly inclined toward the body part 11 with respect to a direction orthogonal to the axial direction. However, the step surface 23 may be a surface perpendicular to the axial direction, or may be an inclined surface slightly inclined toward the bonding surface 22 with respect to the direction orthogonal to the axial direction.

  The laser-transmitting pipe material 2 is formed on a barrel portion 31 that extends in a predetermined length in the axial direction thereof, and on one end side of the barrel portion 31 that is open, and is joined to the laser-absorbing joint end portion 12. And a cylindrical joining end portion 32. The outer peripheral surface of the joining end portion 32 is continuous with the outer peripheral surface of the body portion 31 and has a chamfered tip surface 40. The tip surface 40 is configured to be able to contact the stepped surface 23 in the circumferential direction so as to align with and be received by the stepped surface 23 described above.

  The inner peripheral surface of the joining end portion 32 is formed on the barrel portion 31 side and is inclined by a predetermined angle from the female screw 41 having a diameter larger than the inner diameter of the barrel portion 31 and the distal end side of the female screw 41 to the distal end surface 40. And a joining surface 42.

  The female thread 41 is formed together with the overall shape of the pipe material 2 when the pipe material 2 is molded using various molding methods such as injection molding. The female screw 41 is formed of a parallel female screw extending in a predetermined length in the axial direction corresponding to the male screw 21 formed of a parallel male screw. Due to the screwed structure (engagement structure) of the male screw 21 and the female screw 41, the joining end portions 12 and 32 are engaged with each other. In addition, when the external thread 21 is formed with a tapered external thread, the internal thread 41 is also formed with a tapered internal thread.

  The joining surface 42 is integrally connected to the tip of the female screw 41 and is formed in a reverse taper shape. The joining surface 42 is configured to be aligned with the joining surface 22 and to be able to abut on the joining surface 22 from the outside in the radial direction in the circumferential direction. In addition, it is preferable that the surfaces of the bonding surfaces 22 and 42 are smoothed so that the bonding surfaces 22 and 42 are in contact with each other without a gap. The angles of the bonding surfaces 22 and 42 are arbitrary, but may be any angles that can transmit or receive a laser from a laser torch 50 as a laser irradiation apparatus described later.

  Here, the laser-transmitting and laser-absorbing resins will be described. The laser-transmitting resin constituting the pipe material 2 has thermoplasticity. This laser-transmitting thermoplastic resin only needs to have a laser-transmitting property to such an extent that energy necessary for laser welding reaches the bonding surface 22 on the laser-absorbing side. Therefore, even a laser-transmitting thermoplastic resin may have a slight laser-absorbing characteristic.

  Examples of the laser-transmitting thermoplastic resin include polyethylene, polypropylene, nylon 66, and the like, and those obtained by adding a reinforcing fiber such as glass fiber or a colorant to these may be used. For example, the laser transmissive pipe material 2 is formed in white, translucent or transparent.

  Similarly, the laser-absorbing resin constituting the pipe material 1 has thermoplasticity. The laser-absorbing thermoplastic resin only needs to have an absorptivity with respect to the laser and may be any one that generates heat and melts with the absorbed laser.

  Examples of the laser-absorbing thermoplastic resin include polyethylene, polypropylene, nylon 66, and the like, and those obtained by adding a reinforcing fiber such as glass fiber or a colorant to these may be used. For example, when the laser-absorbing thermoplastic resin is formed of the same resin as the laser-transmitting thermoplastic resin, it is formed by adding more carbon than the laser-transmitting thermoplastic resin. Therefore, the laser-absorbing pipe material 1 is formed in black, for example.

  It should be noted that the entire pipe material 2 is made of a laser-transmitting resin and the entire pipe material 1 is made of a laser-absorbing resin. You may have it. For example, a pair of pipe materials 1 and 2 are both formed of a laser-transmitting resin, and a laser-absorbing absorbent is applied to the joining end (or joining surface) of one of the pipe materials. Or a sheet containing this type of absorbent may be attached.

  Here, a method for joining the two pipe members 1 and 2 will be described with reference to FIG. First, the joining end portion 12 of the pipe material 1 is inserted into the joining end portion 32 of the pipe material 2, and a part of the male screw 21 is screwed into a part of the female screw 41. In order to insert deeper, at least one of the two pipe members 1 and 2 is rotated, and the joint end 12 is screwed with the male screw 21 and the female screw 41 until the joint surface 22 and the joint surface 42 come into contact with each other. Screw into the joint end 32.

  When the joining surfaces 22 and 42 are in contact with each other in the circumferential direction, the male screw 21 and the female screw 41 are screwed in a predetermined length in the axial direction, and the step surface 23 and the tip surface 40 are Are in contact with each other in the circumferential direction. Thereby, a pair of pipe materials 1 and 2 will be in the state joined temporarily (temporary joining). In this state, the boundary between the outer peripheral surface of the joint end portion 12 and the outer peripheral surface of the joint end portion 32 is substantially flush with no gap. Further, the contact between the joint surface 22 and the joint surface 42 when screwing is performed by adjusting the lengths of the male screw 21 and the female screw 41, or the step surface 23 and the tip surface 40 are in contact with each other. This can be confirmed.

  Next, the pair of pipe members 1 and 2 in the temporarily joined state are joined by laser welding. In laser welding, a laser torch 50 disposed outside the pair of pipe members 1 and 2 is driven, and laser emitted from the laser torch 50 is transferred from the laser-transmitting bonding end 32 side to the laser-absorbing bonding end 12. It is done by irradiating towards. The irradiated laser passes through the tip end side of the joining end portion 32 and reaches the laser-absorbing joining surface 22, and heats and melts the resin on the joining surface 22. In addition, the resin of the laser-transmitting bonding surface 42 is heated and melted by heat transfer from the bonding surface 22. The melted resin is cooled and solidified, so that a laser welding portion 60 for joining the joining surfaces 22 and 42 together is formed.

  When the laser torch 50 is being driven, the pair of pipe members 1 and 2 in a temporarily joined state are rotated around their axes by a rotating device (not shown). By doing so, the joining surface 22 is sequentially heated and melted in the circumferential direction, and the joining surface 42 is sequentially heated and melted in the circumferential direction by this heat transfer. Therefore, when the pair of pipe members 1 and 2 in the temporarily bonded state is rotated at least once, the laser welding portion 60 is formed in which the bonding surfaces 22 and 42 are integrally bonded over the circumferential direction. When the laser welding is completed, the pair of pipe materials 1 and 2 is changed from the temporarily joined state to the fully joined state (that is, a completely joined state).

  Note that, for example, if the rotating device rotates the pair of pipe members 1 and 2 so as to tighten the screws, the adhesion between the joint surfaces 22 and 42 can be further enhanced. The pair of pipe members 1 and 2 may be configured to rotate relative to the laser torch 50. Therefore, the laser torch 50 may be directly rotated around the pair of pipe members 1 and 2 instead of directly rotating the pair of pipe members 1 and 2. Alternatively, the pair of pipe members 1 and 2 and the laser torch 50 may be rotated in the same direction or in the opposite direction.

  The laser emitted from the laser torch 50 may be a semiconductor laser or the like, but is not limited to this, and the type of laser includes the thickness of the resin at the laser-transmitting joining end portion 32. It is appropriately selected in consideration of properties and the like. Various conditions such as the laser output (irradiation amount) and the rotation speed of the pair of pipe members 1 and 2 may be set as appropriate according to the properties of the pipe members 1 and 2.

As described above, according to the present embodiment, when the pair of pipe materials 1 and 2 are joined by laser welding, the joining surfaces 22 and 42 are brought into close contact with each other by the screwed structure of the male screw 21 and the female screw 41. Can be held as such. Thereby, it is possible to irradiate the laser while suitably suppressing the positional deviation between the bonding surfaces 22 and 42.
Therefore, the joining surfaces 22 and 42 can be favorably joined by laser welding without using a pressurizing jig or the like. Moreover, since the joint part of a pair of pipe materials 1 and 2 after laser welding is joined not only by the laser weld part 60 but also by screw fastening with a screwing structure, the joint strength and tightness resistance of this joint part. Can be improved.

  Various modifications can be applied to the two-member joint structure of the present embodiment. For example, the threaded male screw 21 and the female screw 41 may be irradiated with laser so that the screwed portions of the male screw 21 and the female screw 41 are also joined by laser welding. In addition, although the joining surface 22 is tapered and the joining surface 42 is inversely tapered, these may of course be formed of a flat surface orthogonal to the axial direction or a surface having a step.

  Furthermore, although the pipe material (1, 2) has been described as an example of the resin member, it can be applied to various resin molded products such as automobile parts and piping parts. For example, even when the intake manifold is composed of a plurality of resin members, the screw structure may be provided as described above, and the resin members may be joined by being irradiated with a laser while being screwed together.

Second Embodiment
Next, with reference to FIG. 4, the two-member joint structure and the joint method according to the second embodiment will be described focusing on the differences. The difference from the first embodiment is that the male screw 21 and the female screw 41 are formed of a metal material. In addition, about the part which is common in 1st Embodiment, the same code | symbol is attached | subjected and the detailed description is abbreviate | omitted.

  The metal sleeve 70 having the external thread 21 on the outer peripheral surface is provided on the outer periphery of a small-diameter cylindrical portion 72 formed on the distal end side of the joining end portion 12. The metal sleeve 70 is formed by insert-molding the pipe material 1. In addition, it can also provide by making it fit to the outer periphery of the small diameter cylindrical part 72, and you may adhere | attach in this fitting state.

  The metal sleeve 80 having the female screw 41 on the inner peripheral surface is provided on the inner periphery of the cylindrical portion 82 formed in the inner portion of the joining end portion 32. Similarly, the metal sleeve 80 is formed by insert molding on the pipe material 2, but of course, the metal sleeve 80 may be fitted to the cylindrical portion 82 or may be bonded in this state. Examples of the metal types of the metal sleeves 70 and 80 include steel, but are not limited thereto. Further, similarly to the above embodiment, the male screw 21 may be formed of a tapered male screw, and the female screw 41 may be formed of a tapered female screw.

  According to this embodiment, since the external thread 21 and the internal thread 41 are made of metal, a stronger fastening force can be obtained compared to the case where they are made of resin. Thereby, the position shift of joining surfaces 22 and 42 can be controlled still more suitably, and joining surfaces 22 and 42 can be joined favorably by laser welding. Also in this embodiment, various modifications as described in the first embodiment can be applied.

  Instead of the metal sleeve 70, a resin sleeve having the male screw 21 on the outer peripheral surface may be configured using a resin harder than the resin of the pipe material 1. Similarly, instead of the metal sleeve 80, a resin sleeve having the internal thread 41 on the inner peripheral surface may be configured using a resin harder than the resin of the pipe material 2.

<Third Embodiment>
Next, with reference to FIG. 5 and FIG. 6, the gas container and its joining method according to the third embodiment will be described. In this embodiment, the two-member joining structure of the first embodiment is applied to a resin liner of a gas container, and the end portions of the liner constituting members constituting the resin liner are joined together. Below, the structure of a gas container is demonstrated first, and the manufacturing method of a gas container is demonstrated easily after that.

  As shown in FIG. 5, the gas container 101 includes a sealed cylindrical container body 102 as a whole, and caps 103, 103 attached to both ends of the container body 102 in the longitudinal direction. The inside of the container main body 102 serves as a storage space 105 for storing various gases. The gas container 101 can be filled with a normal pressure gas, or can be filled with a gas whose pressure is increased as compared with the normal pressure. That is, the gas container 101 of the present invention can function as a high-pressure gas container.

  For example, in a fuel cell system, the fuel gas prepared in a high pressure state is decompressed and used for power generation of the fuel cell. The gas container 101 of the present invention can be applied to store high-pressure fuel gas, and can store hydrogen as a fuel gas, compressed natural gas (CNG gas), and the like. The pressure of hydrogen filled in the gas container 101 is, for example, 35 MPa or 70 MPa, and the pressure of the CNG gas is, for example, 20 MPa. Hereinafter, the high-pressure hydrogen gas container 101 will be described as an example.

  The container body 102 has a two-layer structure of an inner resin liner 111 (inner shell) having gas barrier properties and a reinforcing layer 112 (outer shell) disposed on the outer periphery of the resin liner 111. The reinforcing layer 112 is made of, for example, FRP containing carbon fiber and an epoxy resin, and is wound around so as to cover the outer surface of the resin liner 111.

  The base 103 is formed of a metal such as stainless steel, for example, and is provided at the center of the hemispherical end wall portion of the container body 102. A female screw is engraved on the inner peripheral surface of the opening of the base 103, and functional parts such as piping and valve assembly 114 (valve body) can be screwed into the base 103 via this female screw. ing. In FIG. 5, an example in which the valve assembly 114 is provided only on one of the caps 103 is shown by a two-dot chain line.

  For example, the gas container 101 in the fuel cell system is connected between the storage space 105 and an external gas flow path (not shown) via a valve assembly 114 in which piping elements such as valves and joints are integrated. The storage space 105 is filled with hydrogen and hydrogen is released from the storage space 105. In addition, although the nozzle | cap | dies 103 and 103 were provided in the both ends of the gas container 101, of course, you may provide the nozzle | cap | die 103 only in one edge part.

  The resin liner 111 is formed by joining a pair of liner constituent members 121 and 122 (split bodies) having substantially the same shape divided into two at the center in the longitudinal direction by laser welding. That is, the resin liner 111 inside the hollow is constituted by joining the liner constituting members 121 and 122 of the half hollow body by laser welding.

  Of the pair of liner constituent members 121 and 122, the liner constituent member 121 is formed of, for example, a laser-transmitting thermoplastic resin, like the pipe member 2 of the first embodiment, and the liner constituent member 122 is the first embodiment. Similarly to the pipe material 1, it is formed of a laser-absorbing thermoplastic resin. The pair of liner constituent members 121 and 122 have body portions 131 and 141 extending in a predetermined length in the axial direction of the resin liner 111, respectively. Both end sides in the axial direction of the body portions 131 and 141 are open.

  One liner constituting member 121 includes a return portion 132 formed at a reduced diameter end portion on one end side of the body portion 131, a communication portion 133 opened at a central portion of the return portion 132, and the other end of the body portion 131. And a substantially cylindrical joining end portion 134 on the side. The return portion 132 functions to ensure the strength of the liner constituent member 121. The base 103 is located between the outer peripheral surface of the return part 132 and the end of the reinforcing layer 112, and the base 103 is fitted in the communication part 133.

  The joining end portion 134 is formed in the same manner as the joining end portion 32 of the pipe material 2 of the first embodiment. That is, as shown in FIG. 6, the joint end portion 134 has a tip surface 151 chamfered on the outer peripheral surface, and has a female screw 152 and a joint surface 153 on the inner peripheral surface.

  The tip surface 151, the female screw 152, and the joint surface 153 are configured in the same manner as the tip surface 40, the female screw 41, and the joint surface 42 of the first embodiment. Further, the tip surface 151, the female screw 152, and the joint surface 153 can be applied with the same modified example (for example, a tapered female screw) as in the first embodiment. Here, detailed description thereof is omitted.

  The other liner constituting member 122 includes a return portion 142 formed at a reduced diameter end portion on one end side of the body portion 141, a communication portion 143 opened at the center portion of the return portion 142, and the other end of the body portion 141. And a substantially cylindrical joining end portion 144 on the side.

  The return portion 142 functions to ensure the strength of the liner constituting member 122, and the base 103 is fitted to the communication portion 143. When the base 103 is provided only at one end of the resin liner 111, one end of the body 131 or 141 is formed as a closed end with respect to one of the pair of liner constituting members 121 and 122. .

  The joining end portion 144 is formed in the same manner as the joining end portion 12 of the pipe material 1 of the first embodiment. That is, as shown in FIG. 6, the outer peripheral surface of the joint end portion 144 includes an external thread 161 that is screwed into the female screw 152, and a joint surface 162 that is aligned with the joint surface 153 and abuts on the circumferential surface. And a stepped surface 163 that can receive the front end surface 151.

  The male screw 161, the joint surface 162, and the step surface 163 are configured in the same manner as the male screw 21, the joint surface 22, and the step surface 23 of the first embodiment, and the same modification (for example, a tapered male screw). Can be applied.

  Therefore, in a state where the liner constituting members 121 and 122 of the gas container 101 are joined together, the joining end portions 134 and 144 are engaged with each other by the screwed structure of the male screw 161 and the female screw 152. In this state, a laser welded portion 180 that integrally bonds the bonding surfaces 153 and 162 is formed at the interface between the bonding surface 153 and the bonding surface 162.

  The entire liner constituting member 121 is not laser-permeable and the entire liner constituting member 122 is a laser-absorbing resin, but this kind of laser-transmitting or laser-absorbing property is applied to a portion to be laser welded. You may give a characteristic.

  Here, the liner constituting members 121 and 122 referred to in the present specification are members constituting the resin liner 111 having a split structure, and have a substantially cylindrical end portion as described above. Accordingly, it is sufficient that the liner constituting members 121 and 122 have a substantially cylindrical shape at least on one end side, and the overall shape may be a cylindrical shape, an annular shape, a bowl shape, a dome shape, or the like. included.

With reference to FIG. 3 and FIG. 4, the manufacturing method of the gas container 1 is demonstrated easily.
First, the pair of liner constituting members 121 and 122 and the two caps 103 and 103 are formed. At this time, for example, one pre-molded base 103 is placed in the mold, and a laser-transmitting thermoplastic resin is injected into the mold to integrally form the liner constituting member 121 and the base 103 (insert molding). To do.)

  Further, by the same procedure, a laser-absorbing thermoplastic resin is injected, and the liner constituting member 122 and the base 103 are integrally formed. Thus, each liner constituent member 121, 122 can be molded with good molding accuracy by using injection molding. Instead of injection molding, rotational molding or blow molding may be used.

  Next, the liner constituent members 121 and 122 with the base 103 are disposed in the production facility in a horizontal orientation, for example, so that the liner constituent members 121 and 122 are opposed to each other, and a part of the external thread 161 is fixed to the female screw 152. Screw into a part.

  Then, at least one of the two liner constituting members 121 and 122 is rotated, and the joint end 144 is joined to the joint end while the male screw 161 and the female screw 152 are screwed together until the joint surface 153 and the joint surface 162 come into contact with each other. Screw into part 134. When the screwing is completed, the joint surfaces 153 and 162 are brought into contact with each other in the circumferential direction, and the step surface 163 and the tip surface 151 are brought into contact with each other in the circumferential direction, so that the liner constituting members 121 and 122 are temporarily brought into contact with each other. The resin liner 111 is in a joined state (temporary joining).

  After that, the inside of the resin liner 111 in the temporarily bonded state is made substantially sealed by, for example, screwing and connecting a stopper (not shown) to the caps 103, 103 of the liner constituting members 121, 122. Impurities may be prevented from entering.

  Next, similarly to the first embodiment, a laser welding process is performed. That is, while driving the laser torch 170 outside the temporarily bonded resin liner 111, the resin liner 111 is rotated around its axis by a rotating device (not shown) in synchronization with this. The laser is irradiated from the laser-transmitting bonding end portion 134 toward the laser-absorbing bonding end portion 144, and the resin on the bonding surface 162 and the resin on the bonding surface 153 are sequentially heated and melted in the circumferential direction.

  Note that, for example, if the resin liner 111 is rotated so that the screw is tightened, the rotating device can further improve the adhesion between the joint surfaces 153 and 162. Further, the resin liner 111 may be configured to rotate relative to the laser torch 170 at the time of laser irradiation. Furthermore, a laser emitted from the laser torch 170 can be a semiconductor laser or the like, but is not limited thereto.

  By at least one rotation of the resin liner 111, a laser welding portion 180 that integrally bonds the bonding surfaces 153 and 162 to each other is formed in the circumferential direction. As a result, the resin liner 111 is changed from the temporarily bonded state to the fully bonded state (that is, the state where it is completely bonded). After the laser welding is completed, the gas container 101 is manufactured by forming the reinforcing layer 112 on the outer surface of the resin liner 111 by a filament winding method or the like.

  As described above, according to the present embodiment, when the liner constituent members 121 and 122 of the resin liner 111 are joined to each other by laser welding in the manufacturing process of the gas container 101, the male screw 161 and the female screw 152 are screwed together. Depending on the structure, the joint surfaces 153 and 162 can be held in close contact with each other.

  Therefore, the positional deviation between the bonding surfaces 153 and 162 can be suitably suppressed, and the bonding surfaces 153 and 162 can be favorably bonded to each other by laser welding without using a pressure jig or the like. Moreover, since the resin liner 111 after laser welding is joined not only by the laser welding part 180 but also by screw fastening with a screwing structure, the joining strength and tightness resistance of this joining part can be improved.

  Also in this embodiment, various modifications as described in the first embodiment can be applied. For example, the male screw 161 and the female screw 152 may be irradiated with laser, and the screwed portions of the male screw 161 and the female screw 152 may be joined by laser welding.

  Also in this embodiment, the configuration of the second embodiment in which the male screw 161 and the female screw 152 are metal materials can be applied. In this case, for example, when the liner constituting member 121 (and the base 103) is formed, a metal sleeve (80) having a female screw 152 may be insert-molded into the liner constituting member 121. Similarly, when the liner constituting member 122 (and the base 103) is formed, the metal sleeve (70) having the male screw 161 may be insert-molded into the liner constituting member 122.

<Fourth embodiment>
Next, with reference to FIG. 7, the gas container and its joining method according to the fourth embodiment will be described focusing on the differences. The difference from the third embodiment is that the resin liner 111 of the gas container 101 is composed of three liner constituent members 201, 202, and 203. In FIG. 7, the reinforcing layer 112 is omitted.

  The resin liner 111 is configured by joining three liner constituent members 201, 202, and 203 divided in three in the longitudinal direction by laser welding. The two liner constituting members 201 and 202 located at both ends are formed in a bowl shape as a whole. The liner constituting member 203 located at the center is formed in a cylindrical or annular shape as a whole. The two liner constituting members 201 and 202 at both ends are integrally formed with the base 3 by, for example, injection molding. The central liner constituting member 203 is formed by, for example, injection molding.

  Each of the two liner constituent members 201 and 202 at both ends has joint end portions 213 and 223 on the side opposite to the caps 103 and 103 in addition to the return portions 211 and 221 and the communication portions 212 and 222. The joining end portion 213 and the joining end portion 223 are configured by a joining end portion (134) having the same internal thread 152 as described above, and have laser transmission characteristics.

  The central liner constituting member 203 has joint end portions 231 and 232 on both end sides opened in the axial direction. The joining end portion 231 and the joining end portion 232 are configured by a joining end portion (144) having the same male screw 161 as described above, and have laser absorption characteristics. Of course, the joining end portions 213 and 223 may be a laser-absorbing and screwed male side, and the joining end portions 231 and 232 may be a laser-transmitting and screwing female side. The resin liner 111 is joined to each other by laser welding with the joining end portions 213 and 231 screwed together, and the joining end portions 223 and 232 are joined to each other by laser welding in a screwed state.

  The manufacturing method of each embodiment mentioned above can be applied to the manufacturing method of the gas container 101 of this embodiment. Here, the case where the three liner constituent members 201, 202, 203 are simultaneously joined by laser welding will be briefly described.

  First, three liner constituent members 201, 202, 203 including a liner constituent member (201, 202) with a base 103 are formed. Next, the joint end portion 213 and the joint end portion 231 are screwed together to bring these joint surfaces into contact with each other, and the joint end portion 223 and the joint end portion 232 are screwed together to bring these joint surfaces into contact with each other. . As a result, the resin liner 111 is in a state in which all the liner constituting members 201, 202, 203 are temporarily joined (temporary joined).

  Then, in synchronism with the drive of the two laser torches 170, the joint end portions 213 and 231 and the joint end portions 223 and 232 are surrounded by laser welding while relatively rotating the temporarily bonded resin liner 111 around its axis. Join over direction. As a result, the resin liner 111 is finally joined, and the gas container 101 is manufactured by finally providing the reinforcing layer 112.

  Therefore, even if the resin liner 111 is constituted by three liner constituting members 201, 202, and 203 as in the present embodiment, the gas container 101 can be manufactured in the same manner as in the above embodiment.

  In addition, although the example which performed the process of temporary joining, laser welding, etc. simultaneously about three liner structural members 201,202,203 was demonstrated, of course, you may perform these processes separately. Moreover, although the case where there were three liner structural members was demonstrated, four or more are the same. That is, the present invention can be applied to the resin liner 111 in which a plurality of liner constituent members arranged in the axial direction are joined.

  The gas container 101 of the third embodiment and the fourth embodiment is configured to have a screwed structure including a male screw 161 and a female screw 152 in the laser welded portion 180 itself and in the vicinity thereof. Other engagement structures may be used. For example, you may engage so that the joining end parts 134 and 144 of 3rd Embodiment may be closely_contact | adhered by an engagement structure. This type of engagement structure can be configured by, for example, snap-fit or press-fitting.

  Moreover, in all above-mentioned embodiment, when performing laser welding, it can carry out using various manufacturing equipment. An example applied to the gas container 101 will be described. For example, the temporarily bonded resin liner 111 is disposed in the chamber, and the chamber is placed in an inert gas atmosphere or in a vacuum state, so that the screw-joined joint 134 is formed. 144 may be laser welded together. By doing so, the atmosphere can be under a lower oxygen atmosphere than the atmosphere, and the oxidation of the joints 134 and 144 can be prevented, so that the joining accuracy can be further enhanced.

  Further, a pressure difference may be applied to the inside and outside of the resin liner 111 at the time of laser welding to enhance the adhesion between the joint surfaces (22, 42 or 153, 162). The application of the pressure difference can be performed, for example, by reducing or pressurizing the inside of the resin liner 111 through the base 103 of the resin liner 111 with a pump. By carrying out like this, it can join by the laser welding in the state which raised the contact | adhesion power of joining surface 153,162.

It is sectional drawing which shows the state before joining about the joining structure of 2 members which concerns on 1st Embodiment. It is sectional drawing which shows the state after temporary joining about the joining structure of the 2 member which concerns on 1st Embodiment. It is sectional drawing which shows the state after laser welding about the joining structure of 2 members which concerns on 1st Embodiment. It is sectional drawing which shows the state before joining about the joining structure of the 2 member which concerns on 2nd Embodiment. It is sectional drawing which shows the structure of the gas container which concerns on 3rd Embodiment. It is sectional drawing which expands and shows the junction part of the gas container which concerns on 3rd Embodiment. It is sectional drawing which shows the structure of the gas container which concerns on 4th Embodiment.

Explanation of symbols

  1: pipe material (resin member), 2: pipe material (resin member), 12: joint end, 21: male screw, 32: joint end, 41: female screw, 60: laser weld, 70: metal sleeve 80: metal sleeve, 101: gas container, 111: resin liner, 112: reinforcement layer, 121: liner component, 122: liner component, 134: joint end, 152: female screw, 144: joint end, 161: Male screw, 180: Laser welded part, 201: Liner constituent member, 202: Liner constituent member, 203: Liner constituent member, 213: Joining end part, 223: Joining end part, 231: Joining end part, 232: Joining edge

Claims (20)

A pair of resin members having at least a substantially cylindrical end portion, and a two-member joining structure in which the end portions are engaged with each other by an engaging structure and joined by laser welding,
The engagement structure is
A male screw provided at an end of one resin member;
A two-member joining structure having an internal thread provided at an end of the other resin member and screwed into the external thread. The inner peripheral surface of the end provided with the female screw has an inclined joint surface,
The outer peripheral surface of the end provided with the male screw has a joint surface that is aligned with and abuts the joint surface,
The two-member joint structure according to claim 1, wherein the joint surfaces are joined by laser welding.   The two-member joining structure according to claim 2, wherein the male screw and the female screw in a screwed state are joined together by laser welding together with the joint surfaces. The end provided with the female screw is formed of a laser-transmitting resin,
The two-member joining structure according to claim 2 or 3, wherein the end portion provided with the male screw is formed of a laser-absorbing resin.   The two-member joining structure according to any one of claims 1 to 4, wherein the male screw and the female screw are formed of a metal material. The male screw is a tapered male screw,
The two-member joining structure according to any one of claims 1 to 5, wherein the female screw is a tapered female screw. A two-member joining method for joining a pair of resin members having at least substantially cylindrical end portions, the end portions being joined to each other,
Laser irradiation is performed with the male screw provided at the end of one resin member and the screw provided at the end of the other resin member screwed together, and the ends are joined by laser welding. Two-member joining method.   After the male screw and the female screw are screwed together until the joint surface of the end portion provided with the male screw comes into contact with the joint surface of the end portion provided with the female screw, the joint surfaces are joined together. The joining method of the two members of Claim 7 joined by laser welding.   The two-member joining method according to claim 8, wherein the joining surfaces are joined to each other by laser welding over the circumferential direction.   The end of one resin member is formed of a laser-transmitting resin, and the end of the other resin member is formed of a laser-absorbing resin. The joining method of the two members of Claim 8 or 9 which irradiates a laser toward an edge part, and joins the said joint surfaces by laser welding. A resin liner constituted by joining the liner constituent members using the two-member joining method according to any one of claims 7 to 10 as the pair of resin members as a pair of liner constituent members,
And a reinforcing layer disposed on the outer periphery of the resin liner. A gas container having a resin liner,
The resin liner is formed by joining a plurality of liner constituent members having at least a substantially cylindrical end portion, and the joint portion between the liner constituent members engages with the substantially cylindrical end portions. A structure and a laser welded portion in which the substantially cylindrical ends are joined by laser welding;
The engagement structure is
A male screw provided on one of the ends;
A gas container having a female screw provided on the other of the ends and screwed into the male screw. The inner peripheral surface of the end provided with the female screw has an inclined joint surface,
The outer peripheral surface of the end provided with the male screw has a joint surface that is aligned with and abuts the joint surface,
The gas container according to claim 12, wherein the laser welding portion is formed by melting the joint surfaces. The end provided with the female screw is formed of a laser-transmitting resin,
The gas container according to claim 12 or 13, wherein the end portion provided with the male screw is formed of a laser-absorbing resin.   The gas container according to any one of claims 12 to 14, wherein the male screw and the female screw are formed of a metal material. A method for producing a gas container having a resin liner formed by joining a plurality of liner constituent members having at least a substantially cylindrical end,
An engagement step of engaging the substantially cylindrical end of one liner component to be joined together and the substantially cylindrical end of the other liner component;
After the engagement step, there is an irradiation step of irradiating a laser and joining the ends by laser welding,
The engaging step is performed by screwing a male screw provided at a substantially cylindrical end portion of the one liner constituting member with a screw provided at a substantially cylindrical end portion of the other liner constituting member. The manufacturing method of the gas container performed. In the engaging step, the male screw and the female screw are screwed together until the joint surface of the end portion provided with the male screw comes into contact with the joint surface of the end portion provided with the female screw. Done in
The said irradiation process is a manufacturing method of the gas container of Claim 16 performed by joining the joining surfaces of a contact state by laser welding.   The said irradiation process is a manufacturing method of the gas container of Claim 17 performed by joining the said joint surfaces by the laser welding over the circumferential direction. Prior to the engaging step, the substantially cylindrical end portions of the one liner constituent members to be joined to each other are formed of a laser transmitting resin, and the substantially cylindrical end portions of the other liner constituent members are formed. It further comprises a step of forming with a laser-absorbing resin,
The said irradiation process is performed by irradiating a laser toward the said laser-absorbing edge part from the said laser-permeable edge part side, and joining the said joining surfaces by laser welding. The manufacturing method of the gas container of description.   Prior to the engaging step, the male screw made of a metal material is provided by insert molding to the one liner constituent member to be joined to each other, and from the metal material by insert molding to the other liner constituent member The method for producing a gas container according to any one of claims 16 to 19, further comprising a step of providing the female screw.

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