Patent Grant
11834228
The present invention relates generally to a cap for closing a can container.
Conventionally, a cap for sealing a mouth portion of a can container has a configuration in which a sealing member made of a resin material that comes in close contact with the mouth portion is provided on an inner surface of a cap body. As such a cap, for example, Jpn. Pat. Appln. KOKAI Publication No. 2017-178421 discloses a technique in which a cap body and a sealing member are not bonded to each other in order to reduce opening torque when the cap is opened. Such a sealing member is manufactured by, for example, supplying a molten or softened resin material into the cap body and molding the resin material into a predetermined shape with a mold. The sealing member includes a hard sliding layer having good slidability with respect to a top plate portion on a side facing the top plate portion of the cap body, and a soft sealing layer having good scalability with respect to the mouth portion on a side facing the mouth portion of the can container.
However, in the above-described sealing member, if the thickness of the hard sliding layer is thick, a large load will be required at the time of drawing a corner portion of the cap body when performing capping on the mouth portion of the can container. If the load required for the drawing of the corner portion of the cap body increases, the drawing becomes unstable, which may cause the torque required at the time of opening the cap to increase, or require the container to be strengthened excessively due to the increase in the capping pressure. For this reason, the sliding layer of the sealing member may be considered to be made thinner. However, if the sliding layer is made thinner, the moldability of the sliding layer may deteriorate.
According to an aspect of embodiments, a cap includes a cap body including a disk-shaped top plate portion and a cylindrical skirt portion provided at a peripheral edge portion of the top plate portion; and a disk-shaped sealing member including a sliding layer and a sealing layer, the sliding layer disposed on the top plate portion side and having a thin portion thinner than at least a center side provided on an outer peripheral edge side, and the sealing layer provided on a main surface opposite to the top plate portion side of the sliding layer and sealing a mouth portion of a can container.
Hereinafter, a cap 1 according to a first embodiment of the present invention will be described with reference to
As shown in
Here, the can container 100 is a so-called bottle-shaped container that contains a beverage or the like. For example, the can container 100 is made of a metal material such as an aluminum alloy or a surface-treated steel plate having resin films laminated on both surfaces thereof. The can container 100 is formed in a cylindrical shape having a different outer diameter with one end reduced in diameter. The can container 100 has a mouth portion 110 at one end for discharging the contained beverage. The mouth portion 110 has a jaw portion 111, a male screw portion 112, and a curl portion 113 on the outer peripheral surface thereof from the bottom surface side of the can container 100 toward the end portion.
The jaw portion 111 is configured to protrude annularly. The curl portion 113 is formed to have a smaller diameter than the male screw portion 112. The curl portion 113 is configured to be smaller than the inner diameter of the cap 1. The curl portion 113 is formed by folding the end portion of the mouth portion 110 once or more. The curl portion 113 forms an opening through which the beverage contained in the can container 100 is discharged.
As shown in
The cap body 11 is made of a material obtained by forming a resin coating layer on a metal material such as an aluminum alloy. The cap body 11 is formed by drawing such a thin plate-shaped material into a cup shape and then performing each molding such as knurling and roll-on molding.
The cap body 11 includes a disk-shaped top plate portion 21 and a cylindrical skirt portion 22 provided integrally with a peripheral edge portion of the top plate portion 21. In the cap body 11, the top plate portion 21 and the skirt portion 22 are integrally and continuously formed by an annular and curved corner portion 23.
The top plate portion 21 is formed in a disk shape and has a flat main surface. One end of the skirt portion 22 is continuous with the top plate portion 21 via the corner portion 23, and the other end is open. The skirt portion 22 includes a plurality of knurl portions 31 including a vent slit 31a, a female screw portion 33 and a tamper evidence band portion 34 from an end portion on the top plate portion 21 side to an opened end portion.
As shown in
The knurl portion 31 includes the vent slit 31a and protrudes from the inner peripheral surface of the skirt portion 22. In other words, the knurl portion 31 forms a partially notched protrusion on the inner peripheral surface of the skirt portion 22 by recessing a portion of the skirt portion 22 inward in the radial direction of the skirt portion 22.
The plurality of knurl portions 31 are provided in the circumferential direction of the skirt portion 22. The vent slit 31a is a cut for discharging gas or the like in the can container 100 at the time of opening. The vent slit 31a is formed by cutting an end portion of the knurl portion 31 on the top plate portion 21 side.
The diameters of the tangent circle's connecting the end portions of the plurality of knurl portions 31 on the vent slit 31a side, in other words, the end portions of the plurality of knurl portions 31 on the top plate portion 21 side are set to be smaller than the outer diameter of the sealing member 12. Therefore, the plurality of knurl portions 31 constitute locking portions that restrict movement of the sealing member 12 disposed on the top plate portion 21 in a direction away from the top plate portion 21.
The female screw portion 33 is configured to be screwed with the male screw portion 112 of the can container 100. The female screw portion 33 is molded together with the can container 100. That is, the female screw portion 33 is not molded in the cap 1 before attachment to the can container 100; however, it is molded when being integrally combined with the can container 100.
The tamper evidence band portion 34 engages with the jaw portion 111 of the can container 100 in a direction in which the cap 1 moves away from the can container 100 and in an axial direction of the cap 1. Furthermore, the tamper evidence band portion 34 has a breaking portion 34a which is broken when the cap 1 is opened and is detached from the skirt portion 22. That is, the tamper evidence band portion 34 is configured by forming a slit on the end portion side of the skirt portion 22 while leaving a breaking portion 34a, and is shaped into the shape of the jaw portion 111 of the can container 100 when integrally combined with the can container 100, thereby engaging with the jaw portion 111, in a manner similar to the female screw portion 33. The corner portion 23 is, for example, an annular corner portion whose cross-sectional shape is curved at one center of curvature before the cap body 11 is wound around and compacted on the mouth portion 110 of the can container 100. The corner portion 23 is formed, for example, in an annular corner portion whose cross-sectional shape is curved at at least two centers of curvature by a part of the corner portion 23 being pressed in the axial direction in an annular shape along the circumferential direction at the time of drawing when the cap body 11 is wound and compacted on the mouth portion 110 of the can container 100.
The sealing member 12 is formed separately from the cap body 11. That is, the sealing member 12 is disposed to face the top plate portion 21 and the skirt portion 22, and is not bonded to the cap 1. Specifically, the sealing member 12 is formed in a disk shape and has an outer diameter set to be larger than the diameter of the inscribed circle of the knurl portion 31 provided in the skirt portion 22 of the cap body 11.
The sealing member 12 is provided integrally with the cap body 11 by being engaged in the axial direction of the cap body 11 with the end portion provided with the vent slit 31a of the knurl portion 31 protruding in the radial direction from the inner peripheral surface of the skirt portion 22.
The sealing member 12 includes a disk-shaped sliding layer 41 and a disk-shaped sealing layer 42 integrally laminated on the sliding layer 41. The sealing member 12 is configured by integrally molding the sliding layer 41 and the sealing layer 42 with different resin materials. The sealing member 12 includes a flat plate portion 12a that is uniformly thick, and a curved surface portion 12b in which an outer surface of an outer peripheral edge on the top plate portion 21 side is formed of a curved surface.
In other words, the sealing member 12 is formed in a disk shape, and the ridge portion on the top plate portion 21 side is configured by a curved surface having a predetermined curvature. Furthermore, the sealing member 12 is configured such that the curved surface portion 12b configuring the outer peripheral edge side is thinner than the flat plate portion 12a. In addition, the sealing member 12 is configured such that the curved surface portion 12b becomes gradually thinner from the center side toward the outer peripheral edge, and the distal end of the curved surface portion 12b, that is, the outer peripheral edge, is configured to be thinnest among other portions.
The flat plate portion 12a configures a sealing portion in which a part of the curved surface portion 12b side comes into contact with the mouth portion 110 of the can container 100. The flat plate portion 12a is configured such that the sealing portion that comes in contact with the mouth portion 110 of the can container 100 is formed thicker than the other parts.
The sliding layer 41 is made of a resin material whose hardness is relatively higher (harder) than that of the sealing layer 42. Furthermore, the sliding layer 41 is made of a resin material that does not have adhesiveness and tackiness to the resin coating layer of the cap body 11. That is, the sliding layer 41 is not bonded to the top plate portion 21 and slides on the top plate portion 21 in a state of being in contact with the top plate portion 21.
Examples of the resin material used for the sliding layer 41 include olefin-based resins such as polypropylene resins and polyethylene resins, polyester-based resins such as polyethylene terephthalate, styrene-based resins, and acrylic resins. In the present embodiment, the sliding layer 41 is made of, for example, polypropylene resin. A pigment, a lubricant, a softener, and the like can be appropriately added to the resin material used for the sliding layer 41.
As shown in
The sliding layer 41 includes a first flat plate portion 41a, a first curved surface portion 41b in which an outer surface of an outer peripheral edge on the top plate portion 21 side is formed of a curved surface, a protruding portion 41c provided on the sealing layer 42 side of the first curved surface portion 41b, and a thin portion 41d provided on the first flat plate portion 41a. The first flat plate portion 41a is configured in a manner such that the portion from the center of the sliding layer 41 to the outer peripheral side of a portion facing the curl portion 113 of the mouth portion 110 has a uniform thickness except for the thin portion 41d.
The first curved surface portion 41b is curved on the top plate portion 21 side, so that the thickness of a portion from the outer peripheral side of a portion facing the curl portion 113 of the mouth portion 110 to the outer peripheral edge gradually decreases toward the outer peripheral edge. Furthermore, for example, in the first curved surface portion 41b, a portion adjacent to the first flat plate portion 41a has the same thickness as the first flat plate portion 41a and is set to be thicker than the thin portion 41d.
The protruding portion 41c is provided on the opening side of the skirt portion 22 on the outer peripheral edge of the first curved Surface portion 41b. The protruding portion 41c is configured in an annular protruding shape that is inclined with respect to the axial direction of the sliding layer 41 and the surface direction of the top plate portion 21 and is curved or inclined toward the opening end portion side of the skirt portion 22. The thickness of the protruding portion 41c gradually decreases from the first curved surface portion 41b toward the distal end.
The thin portion 41d is provided on the main surface of the first flat plate portion 41a on the opening side of the skirt portion 22. The thin portion 41d is an annular recess in which the main surface on the opening side of the skirt portion 22 is configured to be parallel to the main surface of the first flat plate portion 41a on the opening side of the skirt portion 22. The thin portion 41d is continuous with the first flat plate portion 41a and the first curved surface portion 41b at inclined surfaces 41d1 and 41d2 inclined with respect to the main surface of the thin portion 41d.
That is, since the thin portion 41d is continuous with portions adjacent to the thin portion 41d on the radially inner and outer sides at the inclined surfaces 41d1 and 41d2, the portions adjacent to the thin portion 41d on the radially inner and outer sides are thicker than the thin portion 41d. In the present embodiment, the portions adjacent to the radially inner and outer sides of the thin portion 41d are the portion of the first flat plate portion 41a excluding the thin portion 41d and the first curved surface portion 41b.
To be more specific, the main surface of the thin portion 41d and the main surface of the first flat plate portion 41a are made continuous by an annular inclined surface 41d1. Here, the inclination angle of the inclined surface 41d1 can be appropriately set as long as the inclined surface 41d1 can guide the resin material of the sealing layer 42 to the thin portion 41d.
The main surface of the thin portion 41d and the main surface of the first curved surface portion 41b are made continuous by an annular inclined surface 41d2. Here, the inclination angle of the inclined surface 41d2 can be appropriately set as long as the inclined surface 41d2 can guide the resin material of the sealing layer 42 to the thin portion 41d.
The thin portion 41d is provided on the main surface side of the first flat plate portion 41a opposite to the top plate portion 21, that is, on the main surface side on which the sealing layer 42 is laminated. In a state where the sealing member 12 is disposed in the cap body 11, the thin portion 41d is provided at a position facing a base point 300 of deformation of the top plate portion 21 when the cap 1 is attached to the can container 100 and drawing of the corner portion 23 of the cap body 11 is performed. Furthermore, the thin portion 41d is provided at a position adjacent to a portion of the sealing layer 42 facing the mouth portion 110 in the axial direction when the cap 1 is attached to the can container 100.
The thin portion 41d has a width in the radial direction formed in such a width to enable the thin portion to be in a position that faces the base point 300 of deformation of the top plate portion 21 at the time of performing drawing and in a position that faces the mouth portion 110 in the axial direction when the sealing member 12 is disposed in the cap body 11 and the cap 1 is placed on the mouth portion 110 of the can container 100. Here, the width of the thin portion 41d in the radial direction is appropriately set in consideration of the difference between the inner diameter of the cap body 11 and the outer diameter of the sealing member 12, the shrinkage rate of the resin material configuring the sliding layer 41 and the sealing layer 42 of the sealing member 12, the amount of deformation of the sliding layer 41 due to external forces, dimensional accuracy, and the like.
The sealing layer 42 is made of a resin material whose hardness is relatively lower (softer) than that of the sliding layer 41. Examples of the resin material used for the sealing layer 42 include an olefin-based resin, polyester-based resin, a styrene-based resin, and an acrylic-based resin, and more preferably include a blended material of a styrene-based elastomer and a polypropylene resin, a blended material of low-density polyethylene and a styrene-based elastomer, and a polyester-based elastomer. In the present embodiment, the sealing layer 42 is made of, for example, a mixed material of a styrene-based elastomer and a polypropylene resin. A pigment, a lubricant, a softener, and the like can be appropriately added to the resin material used for the sealing layer 42.
As shown in
As shown in
The second curved surface portion 42b has, for example, a main surface flush with a main surface of the second flat plate portion 42a facing the curl portion 113. The second curved surface portion 42b is configured in a manner such that the thickness of a portion from the outer peripheral side of a portion facing the curl portion 113 of the mouth portion 110 to the outer peripheral edge is made gradually thinner toward the outer peripheral edge. The second curved surface portion 42b is stacked on the first curved surface portion 41b and the protruding portion 41c. The second curved surface portion 42b configures the curved surface portion 12b of the sealing member 12 together with the first curved surface portion 41b and the protruding portion 41c.
The recess 42c is, for example, an annular recess having a semi-circular cross section. When the sealing member 12 is disposed in the cap body 11, the recess 42c comes into contact with, for example, an end portion of the knurl portion 31 on the vent slit 31a side.
The thick portion 42d corresponds to annular protrusions 42d1 and 42d2 protruding from both main surfaces of the second flat plate portion 42a. A first protrusion 42d1 provided in the thick portion 42d protrudes from the main surface on the sliding layer 41 side of the second flat plate portion 42a of the thick portion 42d and is annular. An annular second protrusion 42d2 protruding from the main surface of the second flat plate portion 42a of the thick portion 42d on the side opposite to the sliding layer 41 side covers the first protrusion 42d1 in the axial direction and has a width wider than that of the first protrusion 42d1 in the radial direction.
The thick portion 42d and the thin portion 41d configure a sealing portion that comes into contact with the mouth portion 110 of the can container 100. The thickness of the thick portion 42d is set so that the difference between the thickness of the thick portion 42d and the thickness of the second flat plate portion 42a becomes larger than the depth of the thin portion 41d from the first flat plate portion 41a. That is, by setting the thickness of the first protrusion 42d1 to be the same as the depth of the thin portion 41d, and by forming the thick portion 42d further including the second protrusion 42d2, the sealing portion of the flat plate portion 12a of the sealing member 12 that comes into contact with the mouth portion 110 is configured to be thicker than the other portions of the flat plate portion 12a.
Specifically, the width of the first protrusion 42d1 in the radial direction is the same as the width of the thin portion 41d. That is, the first protrusion 42d1 has a width in the radial direction such that the first protrusion faces the base point 300 of deformation of the top plate portion 21 at the time of performing drawing and faces the mouth portion 110 in the axial direction when the sealing member 12 is disposed in the cap body 11 and the cap 1 is placed on the mouth portion 110 of the can container 100. Specifically, the second protrusion 42d2 has a width in the radial direction such that the second protrusion faces the mouth portion 110 in the axial direction when the sealing member 12 is disposed in the cap body 11 and the cap 1 is placed on the mouth portion 110 of the can container 100.
Here, the width of the first protrusion 42d1 in the radial direction and the width of the second protrusion 42d2 in the radial direction are appropriately set in consideration of the difference between the inner diameter of the cap body 11 and the outer diameter of the sealing member 12, the shrinkage rate of the resin material configuring the sliding layer 41 and the sealing layer 42 of the sealing member 12, the amount of deformation of the sliding layer 41 due to external forces, dimensional accuracy, and the like.
When the cap 1 is disposed in a state where the top plate portion 21 faces upward and the sealing member 12 falls below the top plate portion 21, the sealing member 12 comes into contact with an end portion of the knurl portion 31 on the vent slit 31a side, whereby the sealing member 12 is locked by the knurl portion 31 and is restricted from moving downward in the direction of gravity. When the cap 1 is placed on the mouth portion 110 of the can container 100, the thick portion 42d of the sealing member 12 comes into contact with the mouth portion 110, and the thin portion 41d of the sealing member 12 is disposed so as to face the base point 300 of deformation of the top plate portion 21 during drawing of the corner portion 23.
A method of manufacturing the cap 1 configured in the above manner will be described below with reference to
First, for example, a metallic plate material is processed, and a cup-shaped molded product is molded from the metallic plate material (step ST11). This molded product is the cap body 11 in which the plurality of knurl portions 31, the female screw portion 33, and the tamper evidence band portion 34 are not molded. That is, the molded product is configured by the top plate portion 21, the cylindrical skirt portion 22 in which the plurality of knurl portions 31, the female screw portion 33, and the tamper evidence band portion 34 are not molded, and the corner portion 23.
Next, the sliding layer 41 is molded (step ST12). As a specific example, for example, the cap body 11 is disposed on a lower mold in a posture in which the top plate portion 21 is positioned on the lower side in the direction of gravity. A molten or softened resin material for the sliding layer 41 is then supplied onto the top plate portion 21, and the supplied resin material is compression-molded by an upper mold to mold the sliding layer 41.
Next, the sealing layer 42 is molded (step ST13). As a specific example, for example, a molten or softened resin material for the sealing layer 42 is supplied onto the sliding layer 41, and the supplied resin material is compression-molded by the upper mold to mold the sealing layer 42 on the sliding layer 41. By these steps, the sealing member 12 in which the sliding layer 41 and the sealing layer 42 are laminated is manufactured in the molded product.
Next, the molded product is processed to mold the cap body 11 (step ST14). As a specific example, the knurl portion 31, the vent slit 31a, the tamper evidence band portion 34, and the like are molded in the skirt portion 22 of the molded product. By this step, the cap body 11 is manufactured. When the cap body 11 is molded, the sealing member 12 is removed from the molded product.
The sealing member 12 is then inserted into the manufactured cap body 11 to manufacture the cap 1 (step ST15). Through these steps, the cap 1 is manufactured.
Next, a beverage or the like is filled in a separately manufactured can container 100. At this time, the can container 100 is in an upright posture in which the mouth portion 110 is positioned at an upper portion. Next, the can container 100 is covered with the cap 1 (step ST16). Specifically, the cap 1 is placed on the mouth portion 110 of the can container 100 with the top plate 21 facing upward.
When the cap 1 is in a posture in which the top plate portion 21 is placed upward, and the sealing member 12 descends by a certain distance in a direction away from the op plate portion 21, the sealing member 12 is supported by the end portion of the knurl portion 31, and the descending movement of the sealing member 12 is restricted. When the cap 1 is placed on the mouth portion 110 in this state, the thick portion 42d of the sealing layer 42 of the sealing member 12 faces the mouth portion 110, and, as shown by ST16 in
Next, the can container 100 is capped with the cap 1 by using a mold 200 of the molding apparatus (step ST17). As a specific example of capping, in a state where the cap 1 covers the mouth portion 110, the corner portion 23 is drawn, then the skirt portion 22 is roll-on molded.
Here, the mold 200 includes a first mold 210 for drawing the corner portion 23, a second mold 220 for roll-on molding the skirt portion 22, and a drive mechanism for driving the first mold 210 and the second mold 220. The first mold 210 includes a fixed mold 211 that comes into contact with the top plate portion 21 and a movable mold 212 that applies a load in the axial direction to the corner portion 23.
As shown in ST17 of
After the molding, by retracting the mold 200 from the cap 1, the cap 1 is wound and compacted on the mouth portion 110 of the can container 100, thereby completing the capping of the cap 1 (step ST16 in
According to the cap 1 configured in the above manner, the thin portion 41d is provided in the sliding layer 41, and at a position facing the base point 300 of the deformation of the top plate portion 21 when the corner portion 23 is drawn. With this configuration, in the cap 1, the deformation of the sliding layer 41 caused by the drawing of the corner portion 23 during the drawing at the time of capping is facilitated, and the drawing moldability of the cap body 11 at the time of capping can be improved.
This effect will be specifically described below. The sliding layer 41 is harder than the sealing layer 42. When the corner portion 23 is drawn, the top plate portion 21 is sandwiched between the first mold 210 and the mouth portion 110 together with the sealing member 12, For this reason, when the drawing of the corner portion 23 is performed, the top plate portion 21 is plastically deformed downward from a portion facing the mouth portion 110 as a base point in the axial direction as illustrated in ST16 and ST17 of
However, in the present embodiment, in the sealing member 12, the thin portion 41d for reducing the bending strength of the sliding layer 41 is provided at a portion facing the base point 300 of the deformation of the top plate portion 21 at the time of drawing the corner portion 23. Therefore, the load required to deform the sliding layer 41 at the time of drawing the corner portion 23 can be reduced. As a result, the cap 1 can reduce the load at the time of drawing, and can be stably drawn. As described above, according to the cap 1 of the present embodiment, the cap body 11 can be suitably drawn.
In addition, it is possible to prevent variations in the shape of the corner portion 23 when the can container 100 is capped with the cap 1. Therefore, it is possible to prevent the torque required for the cap 1 from increasing at the time of opening the cap, and it is not necessary to excessively secure the strength of the can container due to the possibility that the capping pressure may increase.
In the sealing member 12, the sliding layer 41 is configured such that, the outer peripheral side of the thin portion 41d, which in the present embodiment, the end portion on the first flat plate portion 41a side of the first curved surface portion 41b is thicker than the portion of the thin portion 41d. With this configuration, the sealing member 12 can increase the rigidity of the outer peripheral side of the sliding layer 41 even in a configuration in which the thin portion 41d is provided in the sliding layer 41. Therefore, when the sealing member 12 comes into contact with the end portion of the knurl portion 31 on the vent slit 31a side, deformation of the outer peripheral side of the sealing member 12 can be suppressed, and thus the sealing member 12 can be reliably locked to the end portion of the knurl portion 31 on the vent slit 31a side. As a result, the cap 1 can prevent the sealing member 12 from falling off from the cap body 11.
In addition, the sealing member 12 is configured such that the protrusions 42d1 and 42d2 are provided respectively in the portions of both main surfaces of the second flat plate portion 42a of the sealing layer 42 that come into contact with the mouth portion 110, in order to make the sealing portion thicker than the other portions. With this configuration, it is possible to increase the amount of deformation of the sealing layer 42 when coming into close contact with the mouth portion 110, thereby enabling the mouth portion 110 to be reliably sealed.
In addition, by providing the thin portion 41d and the thick portion 42d in the sealing portion of the sealing member 12 with which the mouth portion 110 comes into contact, the ratio of the sealing layer 42 in the sealing portion can be increased. Therefore, when the mouth portion 110 is in close contact with the sealing layer 42, the portion of the mouth portion 110 that is inserted into the sealing layer 42 can be made longer in the axial direction, and thus the seal opening degree of the cap 1 with respect to the mouth portion 110 can be made longer than in a case where the second protrusion 42d2 is not provided. That is, iv when the seal opening degree is increased, it is possible to extend the distance in which the cap 1 rotates until the internal pressure in the can container 100 escapes from the vent slit 31a. Therefore, for example, even if the cap 1 is slightly rotated by accident or deliberately when a bottle can filled with a beverage is displayed, it is possible to prevent the seal from being broken.
Furthermore, the sealing member 12 is configured in a manner that the thin portion 41d and the thick portion 42d are extended in the radial direction. With this configuration, when the cap 1 is placed on the can container 100, the thin portion 41d can be made adjacent to the base point 300 of the deformation of the top plate portion 21 at the time of drawing the corner portion 23 in the axial direction, and the thick portion 42d can be made adjacent to the mouth portion 110. As a result, the cap 1 can reliably achieve the above-described effects even if there are variations in dimensional accuracy in manufacturing the cap body 11 and the sealing member 12, differences in the shrinkage rate in manufacturing the sealing member 12 due to season or the like, radial positional deviation of the sealing member 12 with respect to the cap body 11, and the like.
As described above, according to the cap 1 of the embodiment of the present invention, the sliding layer 41 has good moldability, and the cap body 11 can be suitably drawn.
Note that the present invention is not limited to the above embodiment. For example, in the example described above, the first curved surface portion 41b is configured in a manner that the portion adjacent to the first flat plate portion 41a has the same thickness as the first flat plate portion 41a; however, the present invention is not limited thereto. For example, as in a first modification shown in
In addition, in the example described above, the configuration in which the main surface of the thin portion 41d on the opening side of the skirt portion 22 is an annular recess parallel to the main surface of the first flat plate portion 41a on the opening side of the skirt portion 22 has been described, but the configuration is not limited thereto. For example, as in a third modification shown in
Furthermore, in the example described above, the thin portion 41d has the inclined surface 41d1 at one end in the radial direction, and the main surface of the thin portion 41d and the main surface of the first flat plate portion 41a are made continuous by the inclined surface 41d1. However, the inclination angle of the inclined surface 41d1 may be an angle orthogonal to the main surface of the thin portion 41d and the main surface of the first flat plate portion 41a as in a fourth modification shown in
Furthermore, in the example described above, the configuration in which the thin portion 41d is disposed at the position facing the base point 300 of the deformation of the top plate portion 21 at the time of drawing the corner portion 23 of the cap body 11 has been described, but the configuration is not necessarily limited thereto.
That is, by providing the thin portion 41d in the sliding layer 41, the bending strength of the sliding layer 41 itself decreases. Therefore, even when the thin portion 41d is not disposed at a position facing the base point 300 of the deformation of the top plate portion 21 at the time of drawing the corner portion 23 of the cap body 11, it is possible to reduce the load that deforms the sliding layer 41 when drawing the corner portion 23 compared to a sealing member including a sliding layer that does not have the thin portion 41d. However, in view of the above-described effect, as described above, it is most preferable that the thin portion 41d be disposed at a position facing the base point 300 of the deformation of the top plate portion 21 at the time of drawing the corner portion 23 of the cap body 11.
In addition, in the example described above, the configuration in which the thin portion 41d is provided on the first flat plate portion 41a in a manner adjacent to the first curved surface portion 41b has been described, but the configuration is not limited thereto. For example, the thin portion 41d may be disposed slightly on the axial line side from the end portion on the radially outer side of the first flat plate portion 41a. In this case, the portion adjacent to the radially inner and outer sides of the thin portion 41d is the portion of the first flat plate portion 41a excluding the thin portion 41d.
It should be noted that the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the invention in the implementation stage. In addition, the embodiments may be appropriately combined and implemented, in which case a combined effect is obtained. Furthermore, various inventions are included in the above embodiments, and various inventions can be extracted by a combination selected from a plurality of disclosed constituent elements. For example, even if some constituent elements are deleted from all the constituent elements shown in the embodiments, if the problem can be solved and the effect can be obtained, the configuration from which the constituent elements are deleted can be extracted as the invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2018-205348 | Oct 2018 | JP | national |
This application is a Continuation Application of PCT Application No. PCT JP2019/042544, filed Oct. 30, 2019 and based upon and claiming the benefit of priority from prior Japanese Patent Application No. 2018-205348, filed Oct. 31, 2018, the entire contents of all of which are incorporated herein by reference.
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| Child | 17237214 | US |
