JP4813338B2 - Container cap and packing used therefor - Google Patents

Description

  BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a container cap and a packing used therefor, and more specifically, a synthetic resin container cap having a pilfer proof function widely used in plastic containers typified by PET bottles and the like. It is related with the packing used for.

  Such caps and packings are already known as shown in FIGS. 8 to 10 (see Patent Document 1). FIG. 8 and FIG. 9 show a seal between the inner top plate e formed by the packing d arranged inside the top plate c of the cap body b screwed to the outer periphery of the mouth of the container a and the mouth a1 of the container a. The structure shown in FIG. 10 has a sealing structure with the top a of the cap body b and the mouth a1 of the container a. As in the general case, the seal structure has an inner annular wall f that extends downward from the inner top plate e or the top plate c and closely fits to the inner periphery of the mouth a1 of the container a and the outer periphery of the mouth a1 of the container a. And at least the outer annular wall g opposed to the shoulder. However, at least the inner surface of the outer annular wall g facing the outer periphery of the mouth a1 of the container a has a groove-like airflow extending radially from the outer circumference of the outer annular wall g, that is, from the portion facing the outside air toward the inner annular wall f. It differs from the general point in forming the path h.

As a result, a predetermined sealing function against negative pressure obtained from the prior art is exhibited, and tightening of the lower end side of the outer annular wall g during doming of the inner top plate e or the top plate c by pressurization of the container a is utilized. While increasing the sealing performance against pressure increase, the internal pressure is immediately released to the outside through the groove-shaped ventilation path h at the time of doming due to excessive pressure without causing such deterioration of the sealing performance. Can be prevented from being excessively boosted by secondary fermentation during reclosing.
JP 2006-96396 A

  However, according to the cap body b or the packing d having the sealing structure having the ventilation path h as described above, for example, when an external load is applied to the cap, the deformation is caused by the ventilation path h of the sealing structure portion. In addition, there is a risk that the sealability during normal use may be impaired due to a gap caused by the movement of the packing and the like.

  An object of the present invention is to provide a container cap and a packing used therefor that can ensure high sealing performance while ensuring a function of preventing excessive pressure increase in view of the above points.

In order to achieve the above-described object, the container cap of the present invention has a top plate that has a pressure contact allowance on the top surface of the mouth of the container, and a cylindrical shape continuously connected to the outer periphery of the top plate. A cap body having a body portion having a female screw threadedly fitted on the outer periphery of the container mouth, and a pilfer proof band connected to the body portion of the cap body by a partial connection portion that is separated when the cap body is opened. An inner annular wall extending downward from the top plate of the cap body and closely fitting to the inner periphery of the container mouth, and an outer annular wall facing at least the shoulder at the outer periphery of the container mouth The inner annular wall extends from the lower end portion of the outer annular wall toward the pressure contact portion of the inner surface of the container on the top plate inner surface or at least the inner annular wall facing the container mouth of the outer annular wall. Countless fine or rough surfaces that extend radially to the side That has a convex portion is disposed in the circumferential direction is set to one feature.

  In such a configuration, the inner annular wall of the top plate of the cap body is tightly fitted to the inner periphery of the container mouth, and the outer annular wall is at least opposed to the outer periphery of the container mouth and is on the top surface of the container mouth. Based on the principle of pressure contact, it can exert a predetermined sealing function against the negative pressure obtained from the past, and on this sealing structure, doming that the top plate swells to the outside due to the pressure inside the container is caused to the outer annular wall part The inner annular wall moves to the side away from the container mouth while the outer annular wall moves so as to be pressed against the outer periphery of the container mouth and is arranged in the circumferential direction on the inner surface. Or a roughened surface or a textured surface consisting of micro-projections, or by increasing the degree of pressure contact, generating a gripping force to sandwich the container mouth from the inside or outside by the outer annular wall, or increasing it, or To compensate for the reduction, pull the inner annular wall around the inner periphery of the container mouth. As it is, the sealing performance against boosting is high and it may not be possible to prevent the boosting, but when doming becomes enough to cope with excessive boosting, The rough or textured surface on the inner surface of the outer annular wall is strongly pressed by the mouth of the container, but the inner surface of the outer annular wall between them is slightly lifted from the mouth of the container to ensure a gap, and the cap Through the clearance where the internal pressure is increased by the lifted part from the top surface of the mouth of the container that advances from the outer peripheral position of the inner annular wall of the top plate of the top plate approaching the rough surface or the textured surface Escape to the outside and prevent excessive pressure increase. In addition, the rough surface or textured surface disposed in the circumferential direction on the inner surface of the outer annular wall is a collection of a large number of minute projections, and does not become an element that reduces the deformation rigidity of the outer annular wall. The gap created by it is very small, and the seal part is not easily deformed by an external load acting on the cap. Therefore, the sealing performance against an external load is improved.

The container cap of the present invention also has a top plate that is press-contacted to the top surface of the container mouth and a cylindrical shape on the outer periphery of the top plate and is screwed to the outer periphery of the container mouth on the inner periphery. A cap body having a body portion having a female screw to be joined, and a pilfer proof band connected to the body portion of the cap body by a partial connection portion that is to be detached when the cap body is opened. An inner annular wall that extends downward from the container mouth and tightly fits to the inner periphery of the container mouth, and at least faces the shoulder of the outer periphery of the container mouth, and with the doming that expands to the outside of the top plate due to the pressure increase in the container An outer annular wall provided so as to generate or increase a pressure contact force to the container mouth, and at least on the inner surface side of the outer annular wall facing the container mouth from the lower end of the outer annular wall to the inner surface of the top plate Toward the top of the container's mouth Are separate features that were provided with roughened or embossed surface extending to the inner annular wall in a radial direction with a myriad of minute projections in the circumferential direction extends is.

  In such a configuration, the excessive pressure-increasing prevention function in the case of the container cap of the one characteristic is more reliable or stronger rough surface to the mouth of the container at the time of pressurization less than excessive or stronger. After obtaining pressure contact on the textured surface to further improve the sealing performance, the surface can be more reliably exhibited through the clearance secured on the rough surface or textured surface.

In a further configuration, the outer annular wall and the inner annular wall are integrally provided on the top plate of the cap body.
The effect of the invention of each of the above features is provided by not providing a thin portion that prevents the doming of the top plate of the cap body from extending beyond the outer annular wall and extending between the inner annular walls and between the outer annular walls. Can be demonstrated without any escape.

In the further configuration, the outer annular wall and the inner annular wall are provided on the inner top plate formed by a separate packing disposed inside the top plate of the cap body.
Even if an inner annular plate is provided on the inner top plate formed by a separate packing on the inside of the top plate of the cap body, the inner top plate or the inner top plate and the top plate can be In combination with the phenomenon that the annular wall moves to the side away from the inner periphery of the container mouth, the phenomenon that the rough surface or the textured surface of the inner surface of the outer annular wall is pressed against the outer periphery of the container mouth is obtained. The effect which it plays can be exhibited.

In a further configuration in which the packing forms a lightening portion from the upper surface side between the outer annular walls of the inner top plate,
The cap body separate from the cap body exerts a pulling force from the top of the container on the outer periphery of the packing at a predetermined timing when the cap body is opened. Even if they overlap and the impact is transmitted to the cap, the outer annular wall has high rigidity without a radial groove-like air passage on its inner surface, with the hollow portion between the inner and outer annular walls as a base point. Even if it is a thing, it can prevent that a packing raises early with respect to separation of a pilfer proof band by the deformation | transformation which the outer peripheral side of packing raises.

The container cap of the present invention also has a top plate that is press-contacted to the top surface of the container mouth and a cylindrical shape on the outer periphery of the top plate and is screwed to the outer periphery of the container mouth on the inner periphery. A cap body having a body portion with a female thread to be mated, a pilfer proof band connected to the body portion of the cap body by a partial connection portion that is to be detached when the cap body is opened, and the inside of the top plate of the cap body A separate packing disposed on the inner annular wall that extends downward from the inner top plate formed by the packing and tightly fits to the inner periphery of the container mouth and at least the outer periphery of the container mouth an outer annular wall at least opposite to the shoulder portion, of the packing, the outer surface side of the opposed annular area of the container mouth, from around the outer peripheral surface of the outer annular wall, corresponding to the falling positions of the inner annular wall radially zone to a position on the top plate outer surface among which, in the radial direction That is disposed in the circumferential direction lightening portion formed of fine Rutotomoni outer surface in the thickness direction is set to other features.

In such a configuration, the inner annular wall of the inner top plate of the packing inside the top plate of the cap body is closely fitted to the inner periphery of the mouth of the container, and the outer annular wall is the radial wall on the outer surface side of the top plate. a flat inner surface not related to bleeding portion, in the radial direction zone to the position corresponding to the falling positions of the inner annular wall of the inner top plate on the outer surface from the outer peripheral surface of the outer annular wall, Rutotomoni outer surface extending radially Conventionally obtained based on the basic principle of pressing at the top of the container mouth at least opposite to the outer periphery of the container mouth with flexibility by the thinned portion formed in the thickness direction from the side The sealing function against negative pressure can be exerted more advantageously, and on this sealing structure, when the domes that the top plate swells to the outside due to the pressure inside the container reaches the outer annular wall, the inner annular wall is separated from the container mouth. The outer annular wall is pressed against the outer periphery of the container mouth. To compensate for the increase or decrease of the gripping force that causes the gripping of the container by the outer annular wall from inside to outside. Since the inner annular wall works to attract the inner circumference of the mouth of the container, the dosing may be excessive as it may not be possible to prevent the pressurization without being able to prevent the pressurization with high sealing performance against the pressurization. When the pressure rises to a level corresponding to the pressure increase, it approaches or reaches the flexible portion with the above-mentioned hollow portion on the outer surface side of the packing, and the internal pressure at that time also helps the container mouth including the outer annular wall of the packing. The opposing area is floated from the mouth of the container, and the internal pressure can be immediately released to the outside to prevent excessive pressure increase. In addition, even if the thinned portion is on the outer surface of the packing and the packing is deformed and moved by an external load acting on the cap, there is hardly any gap between the inner surface and the container mouth that releases internal pressure. The sealing performance against external load during use is improved.

In a further configuration in which the outer annular wall is a downwardly bent shape along the outer peripheral edge of the inner top plate of the packing,
Due to the bent shape from the outer periphery of the inner top plate of the outer annular wall and the curved shape in the circumferential direction, the rigidity to follow doming at the outer peripheral portion of the inner top plate of the packing is Regardless of the presence, the pressing force on the outer periphery of the container mouth of the rough or textured surface responding to doming at the outer periphery of the inner top plate, the gripping force on the container mouth in cooperation with the inner annular wall In addition, it is possible to sufficiently ensure the maintenance characteristics of the gap due to the floating between the rough surface of the outer annular wall or the textured surface and the container mouth.

  In a further configuration in which the outer annular wall is close to or in contact with the inner surface of the body of the cap body, if the doming of the top plate of the cap body reaches its outer periphery, the boundary between the upper portion of the body and the top plate that follows. Even if the doming of the inner top plate of the cap is difficult to reach the outer peripheral part due to the influence of the above-mentioned cutout portion, the bent shape part is pressed against the outer periphery of the container mouth from the outside regardless of the reduced diameter of the part. Therefore, in response to the doming of the top plate of the cap body, the pressing force to the outer periphery of the container mouth, the gripping force for the container mouth in cooperation with the inner annular wall are sufficiently secured, and the outer annular wall and the container It can be prevented that the gap between the mouth exceeds the size specified by the rough surface or the textured surface and the pressure not less than the excessive pressure rises. Further, it is easy to prevent the seal structure including the outer annular wall from being deformed or displaced due to an external load acting on the cap, and the sealing performance during normal use can be enhanced.

An air gap is provided between the top plate of the cap body and the inner top plate of the packing.
When opening and closing the cap body, it is possible to prevent the packing from rotating around. The outer annular wall of the packing is pressed against the outer periphery of the container mouth by the rough or textured surface, and the flat inner surface is in close contact. Even if it is of the type to be able to reduce the friction between the packing and the container mouth, it can be prevented from adversely affecting the sealing performance between the two, especially when the container is opened It is possible to prevent the surrounding force from being exerted on the packing that has been caused to cause opening resistance and early opening.

  Moreover, the cap of the container in each case also provides a unique packing unit used in each case.

  Further objects and features of the present invention will become apparent from the following detailed description and drawings. Each feature of the present invention can be used alone or in combination in various combinations as much as possible.

  According to the container cap of one aspect of the present invention, a predetermined sealing function against negative pressure obtained from the prior art is exhibited, and the sealing performance against pressure increase is enhanced by utilizing doming of the top plate by pressure increase in the container. However, without any particular deterioration of the sealing performance, during further doming due to excessive pressurization, the inner pressure of the outer annular wall is arranged in the circumferential direction on the inner surface of the outer annular wall between the rough or textured surfaces. An external load that acts on the cap because it prevents the container from being excessively pressurized by letting it immediately escape to the outside through a minute gap created between the mouth and the strength of the seal structure and packing is not reduced. Therefore, it is possible to avoid the concern that the internal pressure may be lost during normal use below an excessive pressure increase even if it is moved.

  According to another aspect of the present invention, the container cap of the one aspect of the present invention has a more reliable or stronger roughened surface to the mouth of the outer annular wall during pressurization under excessive pressure. After obtaining pressure contact on the textured surface to further improve the sealing performance, the surface can be more reliably exhibited through the clearance secured on the rough surface or textured surface.

  According to the container cap of another feature of the present invention, it is advantageous for improving the sealing performance against negative pressure by the flexibility and the flatness of the inner surface of the outer peripheral surface of the packing and the flatness of the inner surface. While using the top plate doming by boosting to improve the sealing performance against boosting, the sealing performance against boosting may be high, and it may not be possible to prevent boosting. When it reaches a level corresponding to excessive pressurization, the area facing the container mouth, including the outer annular wall, floats from the container mouth using the flexibility of the above-mentioned hollow portion, and the internal pressure is immediately released to the outside excessively. Can be prevented. In addition, the thinned portion on the outer surface of the cap can suppress the deformation of the packing due to the external load acting on the cap, and even if it is moved, there is little gap to allow the internal pressure to escape, and the sealing performance against the external load during normal use is good. improves.

  Hereinafter, an embodiment of a container cap according to the present invention will be described with reference to FIGS. 1 to 7 for the understanding of the present invention. The following description and illustrations are specific examples of the present invention and do not limit the contents described in the claims.

  The cap of the container of this embodiment is intended for a resin cap provided at the mouth of a resin container called a so-called PET bottle. As shown in the example shown in FIG. 1 and the example shown in FIG. 6, the cap C has a circular top plate 5 in a plan view and a mouth 2 a of the container 2 that is continuous in a cylindrical shape on the outer periphery of the top plate 5 and is circular in a plan view. A cap body 1 having a body portion 4 having an internal thread 3 that is screw-fitted with an outer periphery external thread 2b, and a cap body 1 of the cap body 1 of the cap body 1 as shown in FIG. A pilfer proof band 7 connected by a partial connection portion 6 arranged in a circumferential direction called a so-called bridge that is separated from the mouth 2a of the container 2 when the cap is opened. As shown in the example of FIG. 1, the inner annular wall 8 extending downward from the plate 5 and tightly fitting to the inner periphery of the mouth 2 a of the container 2 and at least the shoulder on the outer periphery of the mouth 2 a of the container 2 are at least opposed to each other. Or an outer annular wall 9 that contacts or presses as shown in the example of FIG. There.

  In the example shown in FIG. 1, the inner and outer annular walls 8 and 9 are provided by integrally molding the packing 11 separately from the cap body 1, and the top plate 5 is provided on the top plate 5 a on the cap body 1 side. And the inner top plate 5b that is circular in plan view and placed on the top surface 2c of the mouth 2a of the container 2 on the packing 11 side. The cap body 1 and the pilfer proof band 7 are made of synthetic resin such as high-density polyethylene such as polypropylene, and the partial connection portion 6 is cut 13 by mold molding or using a cutter shown in FIG. Formed by. The packing 11 is made of a relatively soft synthetic resin material for the cap body 1 such as polyethylene, polypropylene and rubber blends, and ethylene vinyl acetate copolymer. In the example shown in FIG. 6, the top plate 5 is formed by the cap body 1 itself, and the inner and outer annular walls 8 and 9 are integrally formed on the top plate 5. A sub-top plate portion fixed by welding or the like may be provided inside, and the inner and outer annular walls 8 and 9 may be integrally formed. In general, when such a sub-top plate is provided, the sub-top plate is formed of a softer material with respect to the packing 11, as will be described below in the present embodiment. It is suitable as a soft grade.

  The cap C as described above is attached to the mouth 2a of the container 2 and closed as shown in FIGS. 1 and 6, and filled with high temperature contents or filled with room temperature contents at a high temperature. The container 2 filled with the heat-treated sterilized high temperature content is sealed. Closing with the cap C is performed by screwing the cap body 1 and the male and female screws 3 and 2b of the container 2 together and screwing the cap body 1 to the mouth 2a of the container 2, and at least the inner annular wall 8 is formed therein. A tight fitting portion 8a formed by a bulging portion in the middle of the circumference has a tight fitting allowance a shown in FIGS. 1 and 6 and is tightly fitted to the inner periphery of the mouth 2a of the container 2 at least at a predetermined fitting depth b. The outer annular wall 9 is opposed to at least the shoulder of the outer periphery of the mouth 2a of the container 2 as shown in FIG. 2, is pressed with a predetermined pressure contact c as shown in FIG. The top surface 2c of the mouth 2a of the container 2 is brought into contact with the inner top plate 5b of the packing 11 shown in FIG. 1 or the top plate 5 of the cap main body 1 alone shown in FIG. The container 2 has a pressure contact allowance d by a projection 15 or the like, To seal the a. In particular, when there is decompression in the container 2 due to cooling to room temperature or storage after refrigeration, the inner top plate 5b of the packing 11 or the top plate 5 of the cap body 1 alone is used as the top surface of the mouth 2a of the container 2. The degree of sealing of the container 2 is increased by being attracted to 2c or the like. Here, when the outer annular wall 9 is in close contact with or crimped to the outer periphery of the mouth 2a of the container 2, the outer annular wall 9 is also adsorbed to the corresponding surface of the outer periphery of the mouth 2a of the container 2, 2 helps to increase the sealing degree.

  On the other hand, when the cap C is plugged into the mouth 2 a of the container 2, the locking portion 14 having a bellows shape in the circumferential direction formed on the pilfer proof band 7 at the closing end stage of the cap C as described above is provided. As shown in FIG. 1 at the same time as the closure is completed, it is reversed from the downward state to the upward state by stretching from the upper side to the annular locking projection 2d integrally formed under the male screw 2b of the mouth 2a of the container 2. As shown in the figure, the reversal is completed and the locking ridge 2d has been climbed downward and engaged with the lower side thereof. The pilfer proof band 7 is also locked in place by the opening operation of the cap body 1. As it is, only the cap body 1 is opened upward as the screw is loosened between the male and female screws 3 and 2b. By utilizing this, the partial connection portion 6 between the cap body 1 and the pilfer proof band 7 is stretched at a predetermined timing of opening, and is broken as shown in FIG. Is left at the initial position of the mouth 2a of the container 2 so that it can be opened only so that the pill fur proof function is exhibited. As long as the cap C has the basic structure as described above, the present invention is effective regardless of what material the container 2 is made of and any shape of the container 2. It can be the container 2 of interest.

  Here, as the internal pressure of the container 2 increases, the top plate 5 of the cap body 1 itself shown in FIG. 6, and accordingly, in the example shown in FIG. 1, the top plate 5a and the inner top plate 5b become virtual as shown in FIG. When the doming phenomenon that swells upward as shown by the line reaches the outer annular wall 9, the inner annular wall 8 is the mouth of the container 2. 1a is moved slightly away from and away from 2a, and the close fitting depth position is slightly shallower from b in FIG. 1 to b1 in FIG. 3, and the tight fitting allowance a shown in FIG. In contrast, in the example shown in FIG. 1, the upper end of the peripheral wall of the body 4 of the cap body 1 contracts from the state shown in FIG. 1 to the state shown by the solid line in FIGS. Depending on the diameter -D, the upper end of the peripheral wall of the body 4 pushes the outer annular wall 9 into F or the inside of the outer annular wall 9. In addition, the inner and outer annular walls 8 and 9 are pressed by pressing at least the shoulder portion of the outer periphery of the mouth 2a of the container 2 or increasing the pressing force F from the state having the initial pressing allowance c1. It is possible to maintain the hermeticity of the container 2 at a high level by generating a gripping force on the mouth 2a of the container 2 in cooperation with each other or increasing it or compensating for it. The same applies to the example of FIG. Here, in the doming of the top plate 5a and the inner top plate 5b by the pressure increase in the container 2 extending to the outer annular wall 9 and the body 4 of the cap body 1, or the doming of the top plate 5, the inner annular wall 8 is the container 2. While the outer annular wall 9 and the body 4 are reduced in diameter, the outer annular wall 9 is moved and pressed against the outer periphery of the mouth 2a of the container 2 while being moved away from the mouth 2a. The inner ring is compensated for by increasing or decreasing the pressure contact and generating a gripping force for pinching the mouth 2a of the container 2 by the inner and outer annular walls 8 and 9 from inside and outside. It is considered that the wall 8 is attracted to the inner periphery of the mouth 2a of the container 2, and this is because the reduced diameter of the outer annular wall 9 or the body 4 is obstructed by the mouth 2a of the container 2. Doming of the inner top plate 5b and doming of the top plate 5 are suppressed at the outer peripheral portion. Is believed to inner away from the mouth 2a of the annular wall 8, also it is equivalent to have suppressed from escaping.

  However, if this is the case, it may occur that the sealing performance against pressure increase is high and the pressure increase cannot be prevented. In order to cope with such a situation, a groove-like ventilation path extending from the outside to the inner annular wall 8 side is formed on the inner surface of the outer annular wall 9 as disclosed in Patent Document 1, as described above. As described above, there is a fear of sealing when an external load is applied to the cap C even during normal use.

  Therefore, in the present embodiment, as in the example shown in FIG. 1 and the example shown in FIG. 6, the outer ring wall 9 has an outer circumference at least on the inner surface side of the opposed annular region facing the mouth 2 a of the container 2. FIG. 2A and FIG. 2B show a rough surface or a textured surface 21 extending in the radial direction from the portion facing the outside air to the inner annular wall 8 side as a detailed schematic diagram of the example shown in FIG. In this way, it is arranged in the circumferential direction with innumerable minute convex portions 21a.

  Thereby, the inner annular wall 8 of the top plate 5a of the cap body 1 is closely fitted to the inner periphery of the mouth 2a of the container 2, and the outer annular wall 9 is at least opposed to the outer periphery of the mouth 2a of the container 2 so that the container 2 Based on the basic principle of being in pressure contact with the top surface 2c of the mouth 2a, it is possible to exert a predetermined sealing function against a negative pressure obtained conventionally. In addition, due to this sealed structure, when the domes in which the top plate 5a and the inner top plate 5b expand to the outside due to the pressure increase in the container 2 reach the outer annular wall 9, the inner annular wall 8 moves to the side away from the mouth 2a of the container 2. On the other hand, the outer annular wall 9 moves so as to be pressed against the outer periphery of the mouth 2a of the container 2 and is a rough surface or a textured surface formed by a number of minute convex portions arranged in the circumferential direction on the inner surface. Compensate that the gripping force that causes the gripping of the mouth 2a of the container 2 from the inside and outside by the inner and outer annular walls 8 and 9 is generated or increased or decreased by pressing at 21 or increasing the pressing degree. The inner annular wall 8 serves to attract the inner periphery of the mouth 2a of the container 2.

  Therefore, although a high sealing function is ensured, it may happen that the sealing performance against pressure increase is high and the pressure increase cannot be prevented. However, in the present embodiment in which the rough surface or the textured surface 21 is provided, the solid line in FIG. 3B is shown in the example shown in FIGS. From the state shown in FIG. 3B to the state shown by the phantom line in FIG. 3B, the tight fitting depth position becomes shallower from b1 to b2, and the tight fitting allowance a1 is further reduced or eliminated, or a gap is generated. However, the rough surface or the textured surface 21 on the inner surface side of the outer annular wall 9 is strongly pressed by the mouth 2a of the container 2, but the inner surface of the outer annular wall 9 between the textured surfaces 21 is illustrated from the mouth 2a of the container 2. As shown in FIG. 2 (c), the gap S is slightly lifted to secure the gap C. Specifically, the top plate 5 of the cap C, specifically the top plate 5a and the inner top plate 5b in the example shown in FIG. In the example shown, the mouth 2a of the container 2 that advances from the outer peripheral position of the inner annular wall 8 to the outer peripheral side of the top plate 5 is shown. Lifting portion from the top surface 2c is able to prevent excessive boosting relief rough surfaces or internal pressure to reach or close to the embossed surface 21 to the outside through the gap S being the assured.

  In addition, the rough surface or textured surface 21 disposed in the circumferential direction on the inner surface of the outer annular wall 9 is a collection of a large number of minute convex portions 21a and does not become an element that reduces the deformation rigidity of the outer annular wall. The height S and the gap S created by the height are small, and the seal portion is not easily deformed by an external load acting on the cap C. The packing 11 in the example shown in FIG. Since the gap S is not immediately connected to the floating from the inside during normal use even if it is moved by the working external load, the sealing performance against the external load is improved.

  Here, the rough surface or the textured surface 21 is a so-called forming of innumerable fine recesses by any of satin processing, electric discharge processing, and blast processing on the corresponding surface area of the mold for forming the cap C and the packing 11. When the cap C or the packing 11 is molded, the rough surface or the textured surface 21 by the infinite number of minute protrusions 21a protruding from the inner surface of the outer annular wall 9 to which the minute recesses are reversely transferred when the cap C or the packing 11 is molded. A radial region extending from the outer periphery of the annular wall 9 toward the inner annular wall 8 is obtained. Therefore, the present embodiment can be realized only by applying a texture processing or the like to a conventional mold that smoothly finishes the inner surface of the outer annular wall 9 and the inner surface of the packing 11 that follows the outer annular wall 9.

  In one embodiment, the depth of the concave portion formed by embossing is set to 18 μm, but the depth is not constant, and the average value Rz of the depth is 15 μm. As described above, the group of the minute convex portions 21a functions to ensure the gap S between the outer annular wall 9 and the outer surface of the mouth 2a of the container 2 without particularly impairing the flexibility of the outer annular wall 9 provided therewith. It is a necessary condition not to be crushed by long-term pressure bonding with the mouth 2a of the container 2 or strong pressure bonding at the time of excessive pressure increase, but innumerable minute convex portions 21a disperse the pressure bonding pressure. I am satisfied with that. However, if the number of the minute protrusions 21a is too large, there is a risk of deterioration in sealing performance when an external load is applied. This is because if there are too many textured surfaces 21, the minute convex portions 21 a are not crushed, and there is a possibility that a gap between the minute convex portions 21 a on each textured surface 21 may remain.

  In the example shown in FIG. 2, the surface area forming the rough surface or the textured surface 21 is a falling base point where the radial range R1 starts to fall with a radius from the inner top plate 5b of the outer annular wall 9 in the packing 11. From the diameter G1 to the diameter G2 that becomes the falling end point that ends falling with a rounded radius, the circumferential range R2 is about 2 mm at each position of θ1 = 72 ° arranged in five equal parts. This is preferably such that the length (circumferential direction) of the packing 11 is 110 mm, and about 10% of the packing 11 is used as the total embossed surface area. Accordingly, the circumferential range R2 is set to about 1.7 mm for each of the six equally spaced positions. However, the condition is not limited to this, and the conditions vary depending on differences in the material, size, shape, etc. of the cap body 1 and the packing 11.

  The radial range R1 is not particularly required to face the outer circumference of the outer annular wall 9, but has a dimension in which the radial extension position toward the inner annular wall 8 side reaches the top surface 2c of the mouth 2a of the container 2. The greater the increase, the faster the internal pressure can be released in response to excessive pressure increase. In the example shown in FIG. 2, the position is slightly set on the outer peripheral side of the top surface 2c. The gap S is ensured between the pressure contact states based on the pressure allowance c1 including the difference in size so that the internal pressure can be released when the pressure increase reaches excessively. In addition, it is preferable that the circumferential range R2 is determined by the number of minute convex portions 21a.

  In the example shown in FIG. 6 as well, a rough surface or a textured surface 21 may be provided on the outer annular wall 9 and the top plate 5 as in the relationship between the outer annular wall 9 and the inner top plate 5b in FIG. .

  The example shown in FIG. 1 will be described in further detail. Between the top plate 5a of the cap body 1 and the inner top plate 5b of the packing 11, an air gap 16 formed by a rough surface contact portion or a gap by a concave portion is provided. Thereby, it is possible to prevent the packing 11 from rotating around when the cap body 1 is opened and closed, and the outer annular wall 9 of the packing 11 in the example shown in FIG. It is possible to prevent the surface or the textured surface 21 from being in pressure contact and reduce the friction between the packing 11 and the mouth 2a of the container 2 and to prevent the sealing performance between them from being adversely affected. Therefore, it is possible to prevent the opening force from being exerted on the packing 11 adsorbed to the second opening 2a and causing opening resistance and early opening.

  The air gap 16 is not limited to the mode shown in FIGS. 1 to 3, and the rough surface also has a top surface of the inner top plate 5 b of the packing 11 and the top plate 5 a of the cap body 1 in order to prevent the packing 11 from rotating. What is necessary is just to provide in the at least one of the contact surfaces between lower surfaces, and you may provide the air introduction path by a groove | channel etc. individually or in combination. The outer annular wall 9 forms a bent portion that is bent downward from the outer peripheral edge of the inner top plate 5b. The inner peripheral surface of the outer annular wall 9 is formed as an inclined surface that is slightly outwardly extended and inclined at an appropriate angle (for example, 33 °), and the lower end surface is formed in a plane perpendicular to the axis. The outer surface is chamfered in accordance with the curved surface of the inner corner portion formed by the top plate 5a and the body portion 4 of the cap body 1. Further, a thin portion is formed on the upper surface of the inner top plate 5b by a thinning 22 from above at a position between the inner and outer annular walls 8 and 9, specifically, in the vicinity of the outer periphery of the base portion of the inner annular wall 8. The resulting meat removal portion 23 is formed. The thinned portion 23 has a circular ring shape in a plan view continuous in the circumferential direction, but is not limited to this, and is not limited to the groove shape and the hollowed portion 22 formed on the hole at a predetermined interval in the circumferential direction. It may be a continuous form. In addition, a packing guide portion 24 constituted by the uppermost portion of the female screw 3 is integrally formed on the inner peripheral surface of the body portion 4 of the cap body 1. The packing 11 is configured to lift the lower end surface of the outer annular wall 9.

  As described above, the outer annular wall 9 of the packing 11 forms a bent portion bent downward from the outer peripheral edge of the inner top plate 5b, and the outer surfaces thereof are the top plate 5a of the cap body 1 and the peripheral wall of the trunk portion 4. The peripheral wall of the body portion 4 of the cap body 1 when the diameter of the peripheral wall of the upper end portion of the body portion 4 due to doming of the top plate 5a and the inner top plate 5b is reduced due to the chamfered shape that matches the curved surface of the inner corner portion formed. There is no play in the action of pressing the outer annular wall 9 against the outer periphery of the mouth 2a of the container 2 by the upper end portion, and even if there is a gap between the outer annular wall 9 and the outer periphery of the mouth 2a of the container 2, the outer annular wall 9 The amount of pressing exceeds that and reliably presses against the mouth 2a of the container 2 to ensure the sealing function against the above-mentioned pressure rise, and the contact between the outer annular wall 9 and the outer periphery of the mouth 2a of the container 2 at the time of closing is cut off. You can keep the resistance of the plug It can be reduced. In particular, even if there is a manufacturing dimensional error in the inner diameter of the outer annular wall 9 or the outer diameter of the mouth 2a of the container 2, the outer annular wall 9 becomes an obstacle and the packing 11 fits tightly into the mouth 2a of the container 2. There is no risk of dying. In this case, the outer annular wall 9 of the packing 11 is easily deformed toward the center of the mouth 2a of the container 2 due to the thinned portion 23 formed in the inner top plate 5b, and the packing 11 is caused by the above pressing force. The outer annular wall 9 is more easily pressed against the outer peripheral surface of the mouth 2a of the container 2, and the clogging resistance can be reduced.

  Further, according to the cap C using the packing 11, the inner top plate 5b of the packing 11 can be used even when the container 2 is stored at a low temperature (for example, 4 to 5 ° C.) due to the presence of the thinned portion 23. The elasticity of the outer periphery can be maintained. Therefore, when the cap C is opened, the partial connecting portion 6 is broken as shown in FIG. 4, and at the same time, the packing guide portion 24 is formed on the lower surface of the outer peripheral portion of the inner top plate 5 b of the packing 11, that is, the lower surface of the outer annular wall 9. Even when abutting, the impact due to the breakage is absorbed and relaxed by the elasticity with the hollow portion 23 on the outer peripheral edge of the inner top plate 5b as the deformation base point, and the impact at the time of abutment is immediately It does not act as a force for lifting the inner annular wall 8. For this reason, generation | occurrence | production of the open state of the timing which airtight is cancelled | released simultaneously with the partial connection part 6 fracture | rupture can be prevented.

  It is desirable that the lower surface of the outer annular wall 9 of the packing 11 be formed in a plane perpendicular to the axis as described above in order to obtain rigidity that prevents the packing 11 from slipping off when opening. However, the present invention is not limited to this, and an appropriate angle (for example, 30 °) may be inclined with respect to the horizontal plane in accordance with the thread inclination angle of the female screw 3 constituting the packing guide portion 24. Moreover, the width | variety of the lightening part 23 is set to 0.1-1.5 mm (preferably 0.3-1.0 mm). If the width is less than that, the resistance to bending is too large, and if it is more than that, the resistance is too soft. When the lower end surface of the outer annular wall 9 of the packing 11 is lifted by the packing guide portion 24 when the plug is opened, the outer circumference of the inner top plate 5b is increased. The portion is bent upward and the engagement with the packing guide portion 24 is disengaged, so-called slipping out easily occurs. The wall thickness of the inner top plate 5b in the thinned portion 23 is set to 0.1 to 0.6 mm (preferably 0.2 to 0.4 mm). Below that, the resistance to bending of the outer peripheral portion with this point as the starting point is too large, and above that, it is too soft, and slipping out easily occurs when the cap is opened.

  Further, the inner peripheral surface of the outer annular wall 9 is formed as an inclined surface inclined at an appropriate angle (for example, 33 °) θ for outward expansion, and its lower end surface is a horizontal plane perpendicular to the axis. In addition to the formation, the inner surface of the inner corner is formed in an arc surface so as to match the curved surface of the outer peripheral corner portion of the mouth 2 a of the container 2. As a result, when the cap C undergoes doming on the top plate 5a as the internal pressure of the container 2 increases, the cap C has a reduced diameter, that is, contraction at the upper portion of the peripheral wall of the body 4 in the cap body 1 due to the doming. The upper end of the peripheral wall can immediately press the outer annular wall 9 against the outer peripheral shoulder of the mouth 2a of the container 2, that is, the corner, with a pressing force of F, and the container 2 is not affected by the inclination of the inner periphery. Airtightness against pressure increase can be kept high. At this time, the outer annular wall 9 is elastically deformed toward the center of the mouth 2a of the container 2 due to the doming of the top plate 5a and the inner top plate 5b by forming the thinned portion 23 on the inner top plate 5b of the packing 11. As a result, the airtight function by the outer annular wall 9 with respect to the outer peripheral corner portion of the mouth 2a of the container 2 is increased, and the above-mentioned pressing force F does not easily reach the inner annular wall 8 due to the presence of the thinned portion 23. Therefore, the airtight function of the inner annular wall 8 with respect to the inner peripheral surface of the mouth 2a of the container 2 can be kept high, and the cap C of the present embodiment can be used for, for example, a so-called hot pack in which the content described above becomes high temperature. Even if it is adopted, the airtightness of the container 2 can be further improved.

  Further, the opening angle of the cap C until the partial connection portion 6 breaks at the time of opening is set to B, the lead of the female screw 3 is set to P, and the lower surface of the outer annular wall 9 and the packing guide portion 24 at the time of closing. Is the distance A between them and the elastic deformation amount of the outer peripheral end of the inner top plate 5b by the packing guide portion 24 at the time of opening is L, the packing guide portion 24 is the lower surface of the outer annular wall 9 at the time of opening. Further, the outer annular wall 9 is further moved to the distance L1 in accordance with the opening so that the opening angle until contact with the opening portion, that is, A / P × 360 ° is smaller than the opening angle B at which the partial connecting portion 6 is broken. The outer annular wall 9 so that the opening angle until the airtightness of the container 2 is released, that is, (A + L1 + L) / P × 360 ° is larger than the opening angle B of the bridge cutting. The bending shape dimension H downward is set. In summary, the downward bending shape dimension H of the outer annular wall 9 is set so as to satisfy the requirement of A / P × 360 ° <B <(A + L1 + L) / P × 360 °.

  Accordingly, when the cap body 1 is rotated in the opening direction at the time of opening, as shown in FIG. 4, the upper end of the engaging portion 14 is changed from the state shown in FIG. 2 to the engaging protrusion 2d as shown in FIG. Since the pilfer proof band 7 is prevented from being lifted further, the partial connecting portion 6 is moved as described above as the cap body 1 is further rotated in the opening direction. Until the partial connecting portion 6 is broken, as shown by a phantom line in FIG. 5 and as shown by a solid line in FIG. The packing guide 24 abuts against the wall 9 and lifts the packing 11 while maintaining airtightness with further opening.

  At the time of this lifting, as shown by a solid line in FIG. 4, the outer peripheral end portion of the inner top plate 5b of the packing 11 is elastically deformed upward by a distance of a deformation amount L, and the outer ring is accompanied by this elastic deformation. The wall 9 may be lifted upward, but the opening angle (leak angle B1) for releasing the airtightness is set to B <(A + L1 + L) / P × 360 °, and the airtightness of the container 2 by the lifting of the outer annular wall 9 is set. Since the partial connection portion 6 is broken before the release is released, the airtightness of the container 2 is not released at all by the lifting of the outer annular wall 9 due to the elastic deformation. That is, by taking the leak angle B1 larger than the opening angle B when the partial connecting portion 6 breaks, the opening function for releasing the airtight after the partial connecting portion 6 is broken can be sufficiently satisfied.

  When the opening operation is further continued, as shown by a solid line in FIG. 4, before the airtightness of the container 2 is released, the outer annular wall 9 is in a state where the outer peripheral end of the inner top plate 5b of the packing 11 is elastically deformed. 4 and 5, the partial connecting portion 6 is broken as shown in FIGS. 4 and 5, and the packing 11 is lifted by the packing guide portion 24, so that the lower side shown in FIG. As shown by the upper phantom line from the phantom line state, as shown by the upper phantom line, when the tightly fitting portion 8a of the inner annular wall 8 moves by the total distance L1, that is, B <(A + L1 + L) / The airtightness of the container 2 is released at an opening angle of P × 360 °.

  In summary, by setting the opening angle so as to satisfy the requirement of A / P × 360 ° <B <(A + L1 + L) / P × 360 °, first, the packing guide portion 24 of the outer annular wall 9 Then, the partial connection portion 6 is broken, and thereafter the airtightness of the container 2 by the outer annular wall 9 is released. Based on the breakage of the partial connection portion 6, the opening of the cap C is performed. I can judge the stopper.

  Here, the amount of elastic deformation L with the packing 11 as the base point of the thinned portion 23 of the outer peripheral portion of the inner top plate 5b is an eigenvalue of the material. In this embodiment, the amount of elastic deformation L is 0.4. It is shape | molded by the polyethylene-type resin which shows. On the other hand, the cap body 1 is made of polypropylene.

  Finally, the outer annular wall 9 of the inner top plate 5 b in the packing 11 and the outer annular wall 9 of the top plate 5 shown in FIG. 6 are bent in a vertical cross section from the inner top plate 5 b and the top plate 5. Due to the shape or drooping shape and the circular curved shape in the horizontal cross section of the outer annular wall 9, the inner top plate 5 b and the top plate 5 have strong rigidity to follow the doming of the top plate 5, and are rough or textured surfaces. Protruding 21 does not reduce it.

  Moreover, the top plate 5a of the cap body 1 shown in FIGS. 1 and 2 or the top plate 5 of the cap body 1 shown in FIG. 6 is thicker than the body portion 4 and substantially extends from the center portion to the body portion 4. This makes the doming easy to reach the body 4 and the outer annular wall 9 integral with them, and has the incompatible functions of sealing against pressure increase using doming and safety to release excessive pressure. It is easy to achieve as set in a well-balanced manner.

  In the example shown in FIG. 7, the packing 11 is an inner ring that extends downward from the inner top plate 5b formed by the packing 11 and closely fits to the inner periphery of the mouth 2a of the container 2 as in the example shown in FIG. Although it has the outer annular wall 9 which at least opposes at least the shoulder on the outer periphery of the wall 2 and the mouth 2a of the container 2, the outer surface side of the annular region facing the mouth 2a of the container 2 of the packing 11 A lightening portion 31 extending radially from the outer periphery of the outer annular wall 9 toward the inner annular wall 8 is disposed in the circumferential direction.

  Accordingly, referring to the similar relationship between the cap body 1 and the packing 11 shown in FIGS. 1 and 3 to 5, the inner top plate 5 b in the packing 11 inside the top plate 5 a of the cap body 1 is arranged. The annular wall 8 is tightly fitted to the inner periphery of the mouth 2a of the container 2, the outer annular wall 9 is a flat inner surface that is not related to the radial cutout portion 31 on the outer surface side, and the flexibility by the cutout portion 31 The sealing principle for negative pressure obtained from the prior art is more advantageously exhibited with the basic principle of having a pressure contact with the top surface 2c of the mouth 2a of the container 2 at least opposed to the outer periphery of the mouth 2a of the container 2. be able to. Due to this sealing structure, when doming that the top plate 5a and the inner top plate 5b bulge to the outside due to the pressure inside the container 2 reaches the outer annular wall 9 part, the inner annular wall 8 moves to the side away from the mouth 2a of the container 2. On the other hand, the outer annular wall 9 moves so as to be pressed against the outer periphery of the mouth 2a of the container 2, or press-contacts or increases the degree of pressure contact, so that the mouth 2a of the container 2 by the outer annular walls 8, 9 is A gripping force for pinching from inside and outside is generated, or compensated for increase or decrease, and the inner annular wall 8 serves to attract the inner periphery of the mouth 2a of the container 2. However, as it is, the sealing performance with respect to boosting is high, and it may happen that the boosting cannot be completely prevented. On the other hand, when the doming reaches the level corresponding to excessive boosting, the packing 11 Approaching or reaching the flexible part with the above-mentioned thinned portion 31 on the outer surface side, the internal pressure at that time also helps, and the area facing the mouth 2a of the container 2 including the outer annular wall 9 of the packing 11 is from the mouth 2a of the container 2 The internal pressure is released to the outside immediately after being floated, and excessive pressure increase can be prevented. In addition, the thinned portion 31 is on the outer surface of the packing 11, and even if the packing 11 is deformed and moved by an external load acting on the cap C, it always keeps a sealed state. The sealing performance against external load is improved. Other features are not particularly different from those of the packing 11 shown in FIGS.

  Here, in consideration of releasing the pressure at the time of excessive pressure increase to the outside, it is preferable that the thickness t1 of the portion where the thinned portion 31 of the packing 11 is provided is thin. However, if it is too thin, the productivity is lowered and the packing 11 may drop off. Considering productivity, the thicker the wall thickness t1 and the smaller the circumferential region R3, the better. However, in order to allow the internal pressure to escape to the outside by deforming the thinned portion 31 when the internal pressure rises, the relationship of R3 / t1 should be in the range of 25 <R3 / t1 <40. It is preferable because the internal pressure can be released when the pressure is increased.

  In consideration of productivity and prevention of the packing 11 from falling off, the wall thickness t1 is about 50% of the original wall thickness t0, and the circumferential direction region R3 at each of the lightening portions 31 is in three equal intervals of θ2 = 120 °. Under conditions, about 10% of the entire circumference is good, and the radial region R4 of the thinned portion 31 is a position having a diameter G3 substantially corresponding to the falling position of the outer annular wall 9 and the inner annular wall 8 on the outer surface of the inner top plate 5b. From the lower surface of the inner top plate 5b on the outer surface of the inner annular wall 8 to the position of the diameter G4 which is the base point to be cut off with a radius, the depth of the wall thickness increases to t1 which becomes 1/2 of t0, The lower end of the outer annular wall 9 is formed so that the bottom surface of the outer annular wall 9 runs parallel to the inner surface of the outer annular wall 9 in the entire region formed by increasing the thickness of the outer annular wall 9 from the top plate 5b and bending downward as described above. It is formed close to the lower end of the outer annular wall 9 and is substantially parallel to its lower surface and larger than the thickness t1. In this configuration, the depth of the thinned portion 31 having a large thickness t3 is increased. Further, both side surfaces in the circumferential direction of the thinned portion 31 give a slight inclination of θ3 narrowing toward the bottom surface of the thinned portion, and each corner portion around the thinned portion 31 differs from the inner top plate 5b depending on its location. Except for the rounded portion with a relatively large dimension R of the bent portion of the annular wall 9, a rounded portion with a minute dimension R is provided so that stress concentration does not occur. Also, the hatched portion of the inner top plate 5b shown in FIG. 7 (b) is a rough surface such as textured to reduce friction with the top plate 5a of the cap body 1.

  However, the conditions are not limited to the above, and the conditions vary depending on differences in materials, dimensions, shapes, etc. of the cap body 1 and the packing 11.

  According to the experiment of the present inventor, the type shown in FIGS. 8 and 9 and the types shown in FIGS. 1 and 2 and the example shown in FIG. When the test method shown in FIG. 11 and the evaluation method shown in FIG. 11 are used to compare the sealing test, the reseal product, that is, the gas leak test and the quick-opening jump test in the re-plugged product, the results shown in FIGS. In the type, the sealability test was good, but in the gas leak test and the quick-opening jump test, both were poor, whereas in the types of the examples of FIGS. 1, 2 and 7, the sealability test was performed. Both the gas leak test and the quick-opening jump test were satisfactory.

  INDUSTRIAL APPLICABILITY The present invention can be applied to a cap having a pilfer proof function that is widely used in plastic containers typified by PET bottles, and is particularly suitable for beverages that undergo secondary fermentation. Prevents excessive pressure increase while ensuring the sealing performance including the case of working.

It is sectional drawing which shows the closure state of one example of the cap of the container which concerns on embodiment of this invention, and its one part enlarged view. FIG. 2 is a partial cross-sectional view showing details of a rough surface or a textured surface of the cap packing of FIG. 1, a bottom view thereof, and an explanatory view showing a relationship between a container mouth. It is explanatory drawing about the sealing effect | action with respect to the pressure | voltage rise in the cap of the closure state of FIG. 1, and the effect | action of prevention of an excessive pressure | voltage rise. It is explanatory drawing which shows the lifting timing of the packing at the time of opening of the cap of the closed state of FIG. It is explanatory drawing which shows the timing of the airtight cancellation | release at the time of opening of the cap of the closure state of FIG. It is sectional drawing of the principal part which shows another example of the cap of the container which concerns on embodiment of this invention. It is a top view of a packing used for a cap of a container concerning an embodiment of the invention, a sectional view, and a side view and a detailed sectional view of a meat removal part. It is sectional drawing which shows the closure state of one example of the conventional cap of a container, and its one part enlarged view. FIG. 9 is a partial cross-sectional view showing details of a rough surface or a textured surface of the packing of the cap of FIG. 8, a bottom view thereof, and an explanatory view showing a relationship with a container opening. It is sectional drawing of the principal part which shows another example of the conventional container cap. FIG. 10 is a comparative view of the sealing performance of the container cap between the example of FIGS. 1 and 2 and FIG. 7 and the example of FIGS.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Cap body 2 Container 2a Port 2b Male screw 3 Female screw 4 Body part 5 Top plate 5a Top plate 5b Inner top plate 6 Partial connection part 7 Pilfer proof band 8 Inner annular wall 9 Outer annular wall 11 Packing 21 Rough surface or wrinkled surface 21a Minute convex part 23 Meat removal part 24 Packing guide part 31 Meat removal part

Claims (15)

There is a top plate that has a pressure contact margin on the top surface of the container mouth, and a body having a female thread that is continuous with the outer periphery of the top plate and is threaded to the outer periphery of the container mouth. A cap body, and a pilfer proof band connected to a body portion of the cap body by a partial connection portion that is to be separated when the cap body is opened,
An inner annular wall extending downward from the top plate of the cap body and tightly fitting to the inner periphery of the mouth of the container, and an outer annular wall at least facing the shoulder at the outer periphery of the mouth of the container;
On the inner annular wall side of the outer annular wall, at least on the inner surface side of the annular region facing the container mouth, from the lower end portion of the outer annular wall toward the pressure contact portion to the top surface of the container mouth on the inner surface of the top plate A container cap characterized in that a rough surface or a textured surface extending in the radial direction is arranged in the circumferential direction with innumerable minute convex portions. There is a top plate that has a pressure contact margin on the top surface of the container mouth, and a body having a female thread that is continuous with the outer periphery of the top plate and is threaded to the outer periphery of the container mouth. A cap body, and a pilfer proof band connected to a body portion of the cap body by a partial connection portion that is to be separated when the cap body is opened,
An inner annular wall that extends downward from the top plate of the cap body and tightly fits to the inner periphery of the container mouth and at least faces the shoulder at the outer periphery of the container mouth, and is external to the top plate by pressure increase in the container An outer annular wall provided so as to generate or increase a pressure-contacting force to the mouth of the container with doming to swell;
On the inner annular wall side of the outer annular wall, at least on the inner surface side of the annular region facing the container mouth, from the lower end portion of the outer annular wall toward the pressure contact portion to the top surface of the container mouth on the inner surface of the top plate A container cap characterized in that a rough surface or a textured surface extending in the radial direction is arranged in the circumferential direction with innumerable minute convex portions.   The container cap according to any one of claims 1 and 2, wherein the outer annular wall and the inner annular wall are integrally provided on the top plate of the cap body.   The container according to any one of claims 1 and 2, wherein the outer annular wall and the inner annular wall are provided on an inner top plate formed by a separate packing disposed inside the top plate of the cap body. Cap.   The container cap according to claim 4, wherein the packing is formed with a lightening portion from the upper surface side between the outer annular walls of the inner top plate. There is a top plate that has a pressure contact margin on the top surface of the container mouth, and a body having a female thread that is continuous with the outer periphery of the top plate and is threaded to the outer periphery of the container mouth. A cap body, a pilfer proof band connected to a body portion of the cap body by a partial connecting portion which is to be disconnected when the cap body is opened, and a separate packing disposed inside the top plate of the cap body. ,
The packing includes an inner annular wall extending downward from an inner top plate formed by the packing and tightly fitting to the inner periphery of the container mouth, and an outer annular wall facing at least the shoulder at the outer periphery of the container mouth. Have
The outer annular wall, of the outer surface of the opposite annular area of the container mouth, the outer from around the outer peripheral surface of the annular wall, to the position of the top plate on the outer surface inner corresponding to the falling positions of the inner annular wall in the radial direction zone, the cap of the container, characterized in that disposed lightening portion formed from Rutotomoni outer surface side to the thickness direction extending radially in the circumferential direction. There is a top plate that has a pressure contact margin on the top surface of the container mouth, and a body having a female thread that is continuous with the outer periphery of the top plate and is threaded to the outer periphery of the container mouth. A cap body, a pilfer proof band connected to a body portion of the cap body by a partial connecting portion which is to be disconnected when the cap body is opened, and a separate packing disposed inside the top plate of the cap body. ,
The packing includes an inner annular wall extending downward from an inner top plate formed by the packing and tightly fitting to the inner periphery of the container mouth, and an outer annular wall facing at least the shoulder at the outer periphery of the container mouth. Have
Packing, of the outer surface of the opposite annular area of the container mouth, the outer from around the outer peripheral surface of the annular wall, the radial range up position of the top plate on the outer surface inner corresponding to the falling positions of the inner annular wall the cap of the container, characterized in that disposed lightening portion formed in the thickness direction from the Rutotomoni outer surface extending radially in the circumferential direction.   8. The container cap according to claim 5, wherein the outer annular wall is a downward bent portion along the outer peripheral edge of the inner top plate of the packing. 9.   The cap of the container according to any one of claims 1 to 8, wherein the outer annular wall is close to or in contact with the inner surface of the body portion of the cap body.   The container cap according to any one of claims 5 to 9, wherein an air gap is provided between the top plate of the cap body and the inner top plate of the packing.   An inner top plate mounted on the top surface of the mouth of the container, an inner annular wall extending downward from the inner top plate and tightly fitting to the inner periphery of the mouth of the container, and at least the shoulder on the outer periphery of the mouth of the container There is an opposing outer annular wall, at least on the inner surface side of the annular region facing the container mouth of the outer annular wall, from the lower end of the outer annular wall toward the pressure contact portion from the top surface of the container mouth on the top plate inner surface. A container cap packing characterized in that a rough surface or a textured surface extending in the radial direction toward the inner annular wall is disposed in the circumferential direction with innumerable minute convex portions. An inner top plate that is placed on the top surface of the mouth of the container and is pressed with a pressure allowance, an inner annular wall that extends downward from the inner top plate and fits tightly to the inner periphery of the mouth of the container, and the mouth of the container So as to generate or increase a pressure contact force to the container mouth as a result of doming that swells to the outside of the top plate of the cap body that is combined with the inner top plate by pressure increase in the container at least opposite to the shoulder at the outer periphery of the container. An outer annular wall provided in the outer annular wall at least on the inner surface side of the annular region facing the container mouth, and a pressure contact portion from the lower end of the outer annular wall to the top surface of the container mouth on the inner surface of the top plate A packing for a cap of a container, characterized in that a rough surface or a textured surface extending in a radial direction toward or on the inner annular wall side is disposed in the circumferential direction with innumerable minute convex portions.   An inner top plate that is placed on the top surface of the mouth of the container and is pressed with a pressure allowance, an inner annular wall that extends downward from the inner top plate and fits tightly to the inner periphery of the mouth of the container, and the mouth of the container An outer annular wall facing at least the shoulder on the outer periphery of the outer annular wall, and on the outer surface side of the outer annular wall facing the container mouth of the outer annular wall from the outer peripheral surface of the outer annular wall to the outer surface of the inner top plate. To the inner annular wall side, a thinning portion from the outer surface side extending in the radial direction toward the pressure contact portion corresponding position to the top surface of the container mouth on the inner top plate inner surface is arranged in the circumferential direction. Packing of the container cap characterized by. An inner top plate mounted on the top surface of the mouth of the container, an inner annular wall extending downward from the inner top plate and tightly fitting to the inner periphery of the mouth of the container, and at least the shoulder on the outer periphery of the mouth of the container Opposite, having an outer annular wall provided so as to generate or increase the pressure contact force to the mouth of the container with doming that swells to the outside of the top plate of the cap body that is combined with the inner top plate by the pressure inside the container, From the outer peripheral surface of the outer annular wall facing the container mouth of the outer annular wall to the inner annular wall side of the inner top plate outer surface to the top surface of the container mouth on the inner top plate inner surface A packing for a cap of a container, characterized in that a thinning portion is provided from an outer surface side extending in a radial direction toward or at a position corresponding to a press contact portion. The packing of the cap of the container according to any one of claims 12 to 14, wherein the outer annular wall is close to or in contact with the inner surface of the body portion of the cap body according to any one of claims 6 to 10. .

Images