JP2018172124A - Container lid - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a novel container lid which reliably prevents a liner 6, in a state of not adhering to inside of a top plate 8 of a shell 4, from incidentally falling off from the shell.SOLUTION: Arc shape slits 32 extending in the circumferential direction are formed at regular intervals in the circumferential direction at the bottom of a ring shape groove 12 which is formed at an upper end of a skirt wall 10 of the shell. Upper cutting edges 34 of the slits are displaced radially inward from a radially inner end at a position of the ring shape groove without slits. The inner diameter of the upper cutting edge is smaller than the outer diameter of the liner, and also the upper cutting edges are located below free end parts 46 of the liner.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a container lid composed of a metal sheet shell and a synthetic resin liner, more specifically a metal sheet shell having a circular top wall and a cylindrical skirt wall depending from the periphery of the top wall. The present invention relates to a container lid composed of a synthetic resin liner having a base layer that is not adhered to the top wall of the shell.

  As a container lid suitably applied to a beverage container containing fruit juice or milk, Patent Document 1 below discloses a container lid composed of a shell made of a thin metal plate such as an aluminum-based alloy thin plate and a liner made of a synthetic resin. Has been. The shell has a circular top wall and a cylindrical skirt wall depending from the periphery of the top wall. The liner has a base layer formed from a relatively hard synthetic resin such as polyprolene and a sealing layer formed from a relatively soft synthetic resin such as a styrenic elastomer. The base layer of the liner is formed by supplying a synthetic resin material to the inner surface of the top wall of the shell and stamping it, and the sealing layer of the liner supplies the synthetic resin material to the lower surface of the base layer, that is, the exposed surface. It is formed by molding. In order to avoid the need for excessive force when opening the container lid when opening the mouth and neck of the container, i.e. rotating in the opening direction, the liner, more particularly its base layer, is It is in a non-bonded state with respect to the inner surface of the top wall. At the upper end portion of the skirt wall of the shell, an annular immersing portion is formed that is radiated radially inward over the entire circumferential direction. The upper end of the skirt wall of the shell is further formed with a knurl in which the concave portion and the convex portion are alternately repeated over the entire circumferential direction below the annular immersive portion, and a slit is formed at the upper end of the concave portion of the knurl. The upper edge of the portion that is formed and defines the recess is displaced radially inward.

Japanese Patent Laid-Open No. 2006-26961

  In the container lid of the above-described form, since the liner is not bonded to the top wall of the shell, it is necessary to reliably prevent the liner from being detached from the shell when the shell is transported. is there. Therefore, in the conventional container lid as described above, the inner diameter of the minimum inner diameter region of the annular immersion portion is set to be smaller than the outer diameter of the liner, and the inner diameter of the upper edge of the portion defining the recess in the knurl is set to the liner. The inner diameter is set smaller than the inner diameter, and the liner is prevented from being detached from the shell by the annular recess and / or the recess in the knurl. However, when the container lid is in an inverted state, the container lid is in an upright state due to the axial separation between the lower surface of the liner (the upper surface in the inverted state) and the annular recess and the knurl recess. Alternatively, the liner may tilt with respect to the inner surface of the top wall of the shell when it is tilted, and the liner may be accidentally detached from the shell. Also, after opening the container lid from the mouth and neck of the container and consuming part of the contents, if the container lid is attached again to the mouth and neck of the container and sealed, for example, fermentation and decay of the contents may occur. The pressure in the progressively sealed container may increase excessively. If the pressure in the sealed container increases excessively, the container lid cannot withstand the pressure in the container, causing the lid to jump, damaging the surrounding people and objects, or contaminating the surroundings with scattered contents. There was a fear.

  The present invention has been made in view of the above-mentioned facts, and the main technical problem thereof is that the liner that is not adhered to the inner surface of the top wall of the shell is accidentally detached from the shell, and To provide a new and improved container lid that reliably prevents excessive pressure buildup within the container.

  As a result of intensive studies and experiments, the inventors have formed an arc-shaped slit extending in the circumferential direction with a circumferential interval in the minimum inner diameter region of the annular immersive portion formed at the upper end of the skirt wall of the shell, The upper cutting edge defining the arc-shaped slit is displaced radially inward from the minimum inner diameter region in the arc-shaped slit non-forming portion of the annular recess, and the inner diameter of the upper cutting edge is smaller than the outer diameter of the liner and It has been found that the above main technical problem can be achieved by configuring the upper cutting edge to be positioned below the free edge portion provided on the outer peripheral edge of the liner.

That is, according to the present invention, as a container lid for achieving the main technical problem, a thin metal plate shell having a circular top surface wall and a cylindrical skirt wall depending from the periphery of the top surface wall; In a container lid composed of a synthetic resin liner having a base layer that is not adhered to the inner surface of the top wall,
At the upper end of the skirt wall of the shell, an annular immersive portion is formed that is radiated inward in the radial direction over the entire circumferential direction, and there is a circumferential interval in the minimum inner diameter region of the annular immersive portion. A plurality of arc-shaped slits extending in the circumferential direction are formed, and the upper cutting edge defining the arc-shaped slit is displaced radially inward from the minimum inner diameter region in the arc-shaped slit non-forming portion of the annular recess. The container is characterized in that the inner diameter of the upper cutting edge is smaller than the outer diameter of the liner, and the upper cutting edge is located below a free edge portion provided on the outer peripheral edge of the liner. A lid is provided.

  Preferably, the base layer of the liner is formed by supplying a synthetic resin material to the inner surface of the top wall of the shell in which the annular recess is already formed and stamping the synthetic resin material, Formed after forming the base layer of the liner. Conveniently, the arcuate slit has a circumferential length of 7 to 12 mm. In a preferred form, the arcuate slit is defined when the boundary area between the top wall and the skirt wall of the shell is deformed downward and radially inward for attachment to the mouth-neck of the container. It is preferable that the upper cutting edge is close to or abuts on the lower surface or outer surface of the outer peripheral edge of the liner. A knurl in which a concave portion and a convex portion are alternately repeated over the entire circumferential direction is formed in a portion below the annular immersive portion at the upper end portion of the skirt wall of the shell. A slit shorter than the arc-shaped slit is formed. The liner has a sealing layer formed by forming the arc-shaped slit in the minimum inner diameter region of the annular recess and then supplying a synthetic resin material to the lower surface of the base layer and embossing the synthetic resin material. Preferably, the outer peripheral edge of the layer is located radially inward of the outer peripheral edge of the base layer, and the inner diameter of the upper cutting edge is larger than the outer diameter of the sealing layer.

  In the container lid of the present invention, the inner diameter of the upper cutting edge that defines the arc-shaped slit formed in the minimum inner diameter region of the annular immersing portion is smaller than the outer diameter of the liner, and the upper cutting edge is provided at the outer peripheral edge of the liner. By being positioned below the free end edge portion, it is ensured that the liner is not accidentally detached from the shell. In addition, in the container lid of the present invention, the arc-shaped slit functions effectively as a so-called vent, and the pressure in the container increases excessively due to abnormal fermentation of the contents contained in the container. Sometimes the shell and liner of the container lid are deformed to release the pressure in the container through the arcuate slit.

The front view which shows a suitable embodiment of the container lid comprised according to this invention in part (circumferential position in which the arc-shaped slit was formed) in a cross section. The front view which shows a suitable embodiment of the container lid comprised according to this invention in part (circumferential position in which the arc-shaped slit is not formed) in a cross section. The front view which shows a part (circumferential position in which the arc-shaped slit was formed) in a cross section in the state which mounted | worn the container neck shown in FIG. 1 in the mouth neck part of the container, and sealed the mouth neck part. The front view which shows a part (circumferential position in which the arc-shaped slit is not formed) in a cross section in a state where the container lid shown in FIG. 1 is attached to the mouth neck of the container and the mouth neck is sealed. The front view which shows a part in cross section the shell preforming body formed in the manufacturing process of the container lid shown in FIG. FIG. 6 is a front view showing a part of the state before the base layer of the liner formed on the shell pre-formed body shown in FIG. The front view which shows a state after the base layer of the liner formed in the shell preform shown in FIG. The front view which shows the state which performed appropriate machining to the shell preform in the state shown in FIG.

  Hereinafter, a preferred embodiment of a container lid constructed according to the present invention will be described in more detail with reference to the accompanying drawings.

  Referring to FIGS. 1 and 2, the container lid, generally designated by numeral 2, constructed in accordance with the present invention is composed of a thin metal shell 4 and a synthetic resin liner 6.

  The shell 4, which can be formed from an appropriate metal thin plate such as an aluminum-based alloy thin plate, has a circular top surface wall 8 and a cylindrical skirt wall 10 depending from the periphery of the top surface wall 8. The boundary region between the top wall 8 and the skirt wall 10 has an arc shape in the cross section. At the upper end portion of the skirt wall 10, an annular immersing portion 12 is formed that is radiated inward in the radial direction over the entire circumferential direction. The annular immersion portion 12 will be further described later. A knurle 18 in which the concave portions 14 and the convex portions 16 are alternately repeated over the entire circumferential direction is formed at a position below the annular recessed portion 12 in the upper end portion of the skirt wall 10. A slit 20 is formed at the upper end of the recess 14 in the knurl 18, and the upper end edge of the portion defining the recess 14 is displaced inward in the radial direction. A circumferentially breakable line 22 is disposed at the lower end of the skirt wall 10, and the skirt wall 10 has a main portion 24 above the circumferentially breakable line 22 and a temper below the circumferentially breakable line 22. It is partitioned into an evidence skirt 26. In the illustrated embodiment, the circumferential breakable line 22 includes a plurality of skirt slits 28 extending in the circumferential direction at intervals in the circumferential direction and a plurality of bridging portions 30 left between the skirt slits 28. The tamper evidence skirt portion 26 is connected to the main portion 24 via a plurality of bridging portions 30.

  A plurality of arc-shaped slits 32 extending in the circumferential direction are formed in the minimum inner diameter region 13 of the annular immersion portion 12 at intervals in the circumferential direction. The upper cutting edge 34 defining the arc-shaped slit 32 is displaced radially inward from the minimum inner diameter region 13 in the portion where the arc-shaped slit 32 of the annular immersive portion 12 does not exist (the portion where the arc-shaped slit is not formed) ( 1 and FIG. 2), the inner diameter of the upper cutting edge 34 is smaller than the outer diameter of the liner 6 and the upper cutting edge 34 is a free edge portion described later provided on the outer peripheral edge of the liner 6. It is important to be located below 46. The circumferential length of the arc-shaped slit 32 is preferably 7 to 12 mm. It is preferable that three or more arc-shaped slits 32 are formed at equal angular intervals in the circumferential direction.

  The liner 6 has a base layer 36 formed from a relatively hard synthetic resin such as polypropylene and a sealing layer 38 formed from a relatively soft synthetic resin such as a styrene elastomer. The base layer 36 is not adhered to the inner surface of the top wall 8 of the shell 4, but the sealing layer 38 is adhered to the lower surface of the base layer 36. The formation process of the liner 6, that is, the base layer 36 and the sealing layer 38 will be described later.

  The base layer 36 extends along the inner surface of the circular thin wall 40 extending along the inner surface of the top wall 8 of the shell 4, the inner surface of the outer peripheral edge of the top wall 8 of the shell 4, and the inner surface of the upper end of the skirt wall 10. It has a ring-shaped thick outer peripheral edge 42. The thin central portion 40 has an annular thickness variation region 44 in which the thickness gradually decreases outward in the radial direction (therefore, the lower surface extends obliquely upward in the radial outward direction). . The outer peripheral edge of the thickness variation region 44 is positioned in the radial direction in the vicinity of an annular protrusion 52 described later of the sealing layer 38. In the outer peripheral edge region of the thick outer peripheral edge portion 42, a free end edge portion 46 whose thickness gradually decreases downward is formed. In the illustrated embodiment, the lower end or free edge of the free edge portion 46 is located proximate above the upper cutting edge 34 of the shell 4.

  The sealing layer 38 is laminated on the thin central portion 40 of the base layer 36. That is, the outer peripheral edge of the sealing layer 38 is located radially inward of the outer peripheral edge of the base layer 36 and is radially inward of the upper cutting edge 34 that defines the arc-shaped slit 32 provided in the skirt wall 10 of the shell 4. Located (in other words, the inner diameter of the upper cutting edge 34 is larger than the outer diameter of the sealing layer 38). The sealing layer 38 has a circular thin central portion 48 and an annular thick outer peripheral edge 50. An annular projecting portion 52 that projects downward exists in the radially inner region of the thick outer peripheral edge portion 50.

  In the container lid of the present invention, the inner diameter of the upper cutting edge 34 that defines the arc-shaped slit 32 formed in the minimum inner diameter region 13 of the annular recess 12 is smaller than the outer diameter of the liner 6 (more specifically, the base layer 36). The upper cutting edge 34 is positioned below the free edge portion 46 provided on the outer peripheral edge portion of the liner 6 (more specifically, the thick outer peripheral edge portion 42 of the base layer 36). Accidental withdrawal is reliably prevented.

  In FIG.1 and FIG.2, the mouth neck part 54 of the container to which the container lid 2 is applied is shown with the dashed-two dotted line. It can be formed from a suitable metal sheet such as a chromic steel sheet, a tin sheet, or an aluminum-based alloy sheet. The mouth / neck part 54 of the container, which is a well-known form, has a generally cylindrical shape as a whole. An outer curl 56 is formed at the upper end where the outer diameter gradually decreases upward. A male thread 58 and a locking jaw 60 positioned below the male thread 58 are formed on the outer peripheral surface of the main part of the mouth and neck part 54.

  When the container lid 2 is attached to the mouth / neck part 54 of the container and the mouth / neck part 54 is sealed, the container lid 2 is fitted onto the mouth / neck part 54 and pressed downward, and the sealing layer 38 of the liner 6 is applied. In a state of being in close contact with the top of the mouth-and-neck portion 54, more specifically, the outer peripheral surface of the annular protrusion 52 of the sealing layer 38 and the radially outer region of the thick outer peripheral edge 50 positioned radially outward from the annular protrusion 52 The boundary region between the top wall 8 and the skirt wall 10 of the shell 4 is set downward and radially inward while maintaining the lower surface of the shell 4 in close contact with the upper or upper surface of the outer circumferential curl 56 of the mouth and neck portion 54. Deformation, that is, deformation into a shape as illustrated in FIGS. Thus, the outer peripheral surface of the annular protrusion 52 of the sealing layer 38 of the liner 6 is in close contact with the upper portion of the inner peripheral surface of the outer curl 56 and is located on the radially outer side of the annular protrusion 52. The lower surface of the outer region in the radial direction is in close contact with the upper surface or the outer peripheral surface of the outer curl 56. At this time, the upper cutting edge 34 defining the arcuate slit 32 is further brought into contact with or in contact with the lower surface or outer surface of the outer peripheral edge of the liner 6. In addition, the main portion 24 of the skirt wall 10 of the shell 4 is deformed along the male screw 58 formed in the mouth-and-neck portion 54 of the container to form the female screw 62, and in the skirt wall 10 of the shell 4. The lower end portion of the tamper evidence skirt portion 26 is deformed inward in the radial direction and is locked to the locking jaw portion 60 in the mouth neck portion 54 of the container.

  In the container lid of the present invention, the arc-shaped slit 32 formed in the minimum inner diameter region 13 of the annular immersion portion 12 effectively functions as a so-called vent, and the contents contained in the container are abnormally fermented. When the pressure in the container increases excessively, the shell 4 and the liner 6 of the container lid 2 are deformed, and the pressure in the container is released through the arc-shaped slit 32.

  The arc-shaped slit 32 will be described more specifically. In a container lid having a nominal diameter of 38 mm, three arc-shaped slits 32 are formed at intervals in the circumferential direction, and the circumferential length of the arc-shaped slit 32 is 7 to 12 mm. The arcuate slit 32 is preferably located 1.5 to 2.5 mm below the lower surface of the top wall 8. And when opening a container lid, it is preferable to open | release the pressure in a container by the predetermined value set by 0.6 thru | or 1.0 MPa. When the circumferential length of the arc-shaped slit 32 is too small, the pressure in the container cannot be released at a predetermined value, and so-called lid jumping may occur, and the circumferential length of the arc-shaped slit 32 is excessive. In some cases, the pressure in the container may be released at a value lower than a predetermined value.

  When opening the mouth-and-neck part 54 to consume the contents of the container, a finger is placed on the skirt wall 10 of the shell 4 to open the container lid 2 in the opening direction, that is, as viewed from above in FIGS. Rotate clockwise. In the initial stage of the rotation, the liner 6, more specifically, the base layer 36 is not adhered to the inner surface of the top wall 8 of the shell 4, and only the shell 4 rotates with respect to the liner 6. The container lid 2 can be easily rotated with respect to the mouth-and-neck portion 54 without need. When the shell 4 is rotated with respect to the mouth-and-neck portion 54, the female screw 62 formed in the main portion 24 of the skirt wall 10 moves along the male screw 58 of the mouth-and-neck portion 54. Is moved upward relative to the mouth-and-neck portion 54. At this time, the shell 4 is moved upward with respect to the mouth-and-neck portion 54, and the liner 6 is also provided with a free edge portion 46 provided on the thick outer peripheral edge 42 by the upper cutting edge 34 of the arc-shaped slit 32. Since the outer side surface or the lower surface of the head is reliably supported, it is moved upward with respect to the mouth-and-neck portion 54 without being tilted and falling off. At this time, when three arc-shaped slits 32 are formed in the annular recess 12 at equal angular intervals in the circumferential direction, the upper cutting is performed even if the liner 6 tilts in any radial direction with respect to the shell 4. It can be supported by the edge 34.

  When the container lid 2 is moved upward with respect to the mouth-and-neck portion 54, the tamper-evidence skirt portion 26 of the skirt wall 10 is formed upward because the lower end portion is formed on the locking jaw portion 60 of the mouth-and-neck portion 54. Is prevented, and stress is generated in the bridging portion 30 of the circumferentially breakable line 22 formed in the skirt wall 10 to break the bridging portion 30. Thereafter, the container lid 2 moves upward with rotation while leaving the tamper evidence skirt portion 26 and is detached from the mouth neck portion 54, and the mouth neck portion 54 is opened.

  Next, with reference to FIGS. 5 to 8, a preferred mode of the manufacturing process of the container lid 2 will be described as follows. First, an appropriate machining is applied to a thin metal plate having a weak adhesive applied on one side in advance to form a shell pre-formed body 64 shown in FIG. The weak adhesive is applied to the inner surface of the shell preform 64, that is, the surface that will later become the inner surface of the shell 4. As the weak adhesive, those mainly composed of known components such as a paint containing a polypropylene adhesive component can be used. Only the annular recess 12 'is formed on the outer peripheral surface of the skirt wall 10' of the shell pre-formed body 64, and the arc-shaped slit 32 'is not formed (the number indicated by' is a shell that is a completed body). 4 is the number of each corresponding part in the same. Next, as shown in FIG. 6, a synthetic resin material is supplied to the inner surface of the top surface wall 8 'of the shell pre-formed body 64 (that is, the inner surface of the top surface wall of the shell in which the annular recess is already formed), and this is embossed. The base layer 36 of the liner 6 is formed by molding. More specifically, the base layer 36 holds the shell pre-formed body 64 in an inverted state and holds it on a base (not shown), and supplies a soft and melted synthetic resin material to the central portion of the top surface wall 8 '. The synthetic resin material is formed by pressing a stamping member (not shown) having a required shape with a required pressure. Immediately after the base layer 36 is formed on the inner surface of the top wall 8 'of the shell preform 64, the weak adhesive applied to the inner surface of the top wall 8' is clearly shown in FIG. The base layer 36 is adhered to the inner surface of the top wall 8 '. However, after a predetermined time has elapsed after the base layer 36 is formed on the inner surface of the top wall 8 'of the shell preform 64, the base layer 36 cools and contracts as shown in FIG. The adhesive peels off. As a result, the base layer 36 is not adhered to the inner surface of the top wall 8 '. Thereafter, the shell pre-formed body 64 is appropriately machined to form the shell 4 as shown in FIG. At this time, an arc-shaped slit 32 ′ is formed at the immersing end edge of the annular immersing portion 12 ′ of the shell preform 64. After that (in other words, after forming a slit at the immersing edge of the annular immersive portion), the sealing layer 38 of the liner 6 is formed by stamping the synthetic resin material supplied to the lower surface of the base layer 36 of the liner 6. Form (FIG. 1). More specifically, the sealing layer 38 holds the shell 4 formed with the base layer 36 in an inverted state and holds it on a base (not shown), and supplies a soft and molten synthetic resin material to the center of the base layer 36. The synthetic resin material is formed by pressing a stamping member (not shown) having a required shape with a required pressure.

2: Container lid 4: Shell 6: Liner 8: Top wall 10: Skirt wall 12: Annular intrusion 13: Minimum inner diameter region 32: Arc-shaped slit 34: Upper cut edge (which defines the slit) 36: Base layer 46: Free edge part (of the liner)

Claims (6)

Synthetic resin liner having a thin sheet metal shell having a circular top wall and a cylindrical skirt wall depending from the peripheral edge of the top wall, and a base layer that is not bonded to the inner surface of the top wall of the shell In a container lid composed of
At the upper end of the skirt wall of the shell, an annular immersive portion is formed that is radiated inward in the radial direction over the entire circumferential direction, and there is a circumferential interval in the minimum inner diameter region of the annular immersive portion. A plurality of arc-shaped slits extending in the circumferential direction are formed, and the upper cutting edge defining the arc-shaped slit is displaced radially inward from the minimum inner diameter region in the arc-shaped slit non-forming portion of the annular recess. The container is characterized in that the inner diameter of the upper cutting edge is smaller than the outer diameter of the liner, and the upper cutting edge is located below a free edge portion provided on the outer peripheral edge of the liner. lid.   The base layer of the liner is formed by supplying a synthetic resin material to the inner surface of the top wall of the shell where the annular recess is already formed, and stamping the synthetic resin material, and the arc-shaped slit is formed on the liner. The container lid according to claim 1, which is formed after the base layer is formed.   The container lid according to claim 1, wherein a circumferential length of the arc-shaped slit is 7 to 12 mm.   When the boundary area between the top wall and the skirt wall of the shell is deformed downward and radially inward for attachment to the mouth and neck of the container, the upper cutting edge defining the arcuate slit is the The container lid according to any one of claims 1 to 3, wherein the container lid is in contact with or in contact with a lower surface or an outer surface of the outer peripheral edge of the liner.   A knurl in which a concave portion and a convex portion are alternately repeated over the entire circumferential direction is formed in a portion below the annular immersive portion at the upper end portion of the skirt wall of the shell. The container lid according to any one of claims 1 to 4, wherein a slit shorter than the arc-shaped slit is formed.   The liner has a sealing layer formed by forming the arc-shaped slit in the minimum inner diameter region of the annular recess and then supplying a synthetic resin material to the lower surface of the base layer and embossing the synthetic resin material. The container lid according to any one of claims 1 to 3, wherein an outer peripheral edge of the layer is located radially inward from an outer peripheral edge of the base layer, and an inner diameter of the upper cutting edge is larger than an outer diameter of the sealing layer. .