Patent Grant
7059501
The present invention relates to a valve mechanism, particularly to a valve mechanism which can be used for a tube-type fluid container.
As this type of valve mechanism, for example, as described in Japanese Patent Laid-open No. 2001-179139, a valve mechanism having a spherical valve body and a spring for giving momentum to the valve body toward a valve seat has been used. Manufacturing costs of the valve mechanism using the spherical valve body and the spring, however, tend to be high.
Consequently, a valve mechanism having a resinous valve seat, and a resinous valve body which moves between a closed position in which the valve body contacts the valve seat and an open position in which the valve body separates from the valve seat is commonly used.
In the resinous valve mechanism, it is preferred that the valve mechanism has a simple configuration which can close a fluid flow reliably. Additionally, it is preferred that the configuration can alter a flow rate of the fluid passing through the valve mechanism discretionally according to a pressure applied to the fluid. As matters stand, however, a valve mechanism satisfying these requirements is not reported.
The present invention has been achieved to solve the above-mentioned problems. It aims to provide a valve mechanism which can close a fluid reliably while its configuration is simple and which can alter a flow rate of the fluid passing through the valve mechanism discretionally according to a pressure applied to the fluid.
The present invention includes, but is not limited to, the following embodiments. Solely for the sake of understanding some embodiments of the present invention easily, reference numerals used in the figures explained later are referred to. However, the present invention is not limited to the structures defined by these reference numerals, and any suitable combination of elements indicated by these reference numerals can be accomplished.
In an embodiment, a valve mechanism adapted for a mouth portion (or a fluid dispensing port; e.g., 141) of a tube-type fluid container (e.g. 140, 1140) may comprise: (I) a valve seat portion (e.g., 20, 220) being cup-shaped having an opening (e.g., 23, 26) at its bottom through which a fluid passes, said valve seat portion having an inner wall (e.g., 201); and (II) a resinous valve portion (e.g., 10, 30, 40, 50, 60, 70) comprising: (i) a valve body (e.g., 12, 42, 52, 62, 72) having a shape corresponding to said opening; (ii) an annular support (e.g., 11, 41, 51, 61, 71) fixedly attached to the inner wall of the valve seat portion; and (iii) multiple connectors (e.g., 13, 43, 53, 63, 73) connecting the valve body and the support, said connectors elastically urging the valve body downward to close the opening and being outwardly bendable as the valve body moves upward, wherein when the valve body is moved upward to open the opening, the connectors move outward toward the inner wall (e.g., in a radial direction). In an embodiment, the connectors may be substantially or completely in contact with the inner wall (e.g., 101, 301, 401, 501, 601, 701) when moving outward and may restrict a further upward movement of the valve body.
In the above, the valve mechanism may include, but is not limited to, the following configurations:
The connectors may comprise at least three coupling portions (e.g., 13, 43, 53, 63, 73, 79). The coupling portions may have flections (e.g., 14, 44, 54, 64). The valve mechanism may further comprise a guide mechanism (e.g., 29, 16, 76, 77) which guides an upward and downward movement of the valve body. The guide mechanism may comprise (a) a vertical guide pin (e.g., 29) provided in said valve body and (b) a hole portion (e.g., 16) having a hole (e.g., 19) wherein the guide pin is inserted, said hole portion being attached to an inner wall (e.g., 302) of the valve seat portion. Alternatively, the guide mechanism may comprise (a) a guide plate (e.g., 77) having an outer diameter smaller than an inner diameter of the annular support and being slidable against an inner wall (e.g., 702) of the annular support, and (b) a rod (e.g., 76) connecting the guide plate and the valve body. Each of the valve seat portion and the valve portion may be formed with a single integrated piece made of a resin.
In an embodiment, the valve seat portion (e.g., 220) may be comprised of a cylindrical support (e.g., 221) having an upper opening (e.g., 225) and a lower opening (e.g., 226), through which a fluid passes; and a valve seat (e.g., 122) having an opening (e.g., 123) at its bottom through which the fluid passes, said valve seat being fitted in inside the lower opening of the cylindrical support.
In another embodiment, a valve mechanism adapted for a mouth portion of a tube-type fluid container (e.g., 140, 1140) may comprise: (I) a valve seat portion (e.g., 20, 220) being cup-shaped having an opening (e.g., 23) at its bottom through which a fluid passes, said valve seat portion having an inner wall (e.g., 201); (II) a resinous valve portion (e.g., 30, 70) comprising: (i) a valve body (e.g., 12, 72) having a shape corresponding to said opening; (ii) an annular support (e.g., 11, 71) fixedly attached to the inner wall of the valve seat portion; and (iii) multiple connectors (e.g., 13, 73, 79) connecting the valve body and the support, said connectors elastically urging the valve body downward to close the opening and being bendable as the valve body moves upward; and (RI) a guide mechanism (e.g., 29, 16, 76, 77) which guides an upward and downward movement of the valve body and restricts a sideways movement of the valve body.
In the above, the valve mechanism may include, but is not limited to, the following configurations:
The guide mechanism may not be subject to deformation (e.g., 29, 16, 76, 77). The guide mechanism may comprise (a), a vertical guide pin (e.g., 29) provided in said valve body and (b) a hole portion (e.g., 16) having a hole (e.g., 19) wherein the guide pin is inserted, said hole portion being attached to an inner wall (e.g., 201) of the valve seat portion. The guide mechanism may comprise (a) a guide plate (e.g., 77) having an outer diameter smaller than an inner diameter of the annular support and being slidable against an inner wall (e.g., 702, 702′) of the annular support, and (b) a rod (e.g., 76) connecting the guide plate and the valve body. The connectors may comprise at least three coupling portions (e.g., 13, 73, 79). The coupling portions may have flections (e.g., 14).
In an embodiment, the valve seat portion (e.g., 220) may be comprised of a cylindrical support (e.g., 221) having an upper opening (e.g., 225) and a lower opening (e.g., 226), through which a fluid passes; and a valve seat (e.g., 122) having an opening (e.g., 123) at its bottom through which the fluid passes, said valve seat being fitted in inside the lower opening of the cylindrical support.
In still another embodiment, a valve mechanism adapted for a mouth portion of a tube-type fluid container (e.g., 140, 1140) may comprise: (I) a cylindrical support (e.g., 221) having an upper opening (e.g., 225) and a lower opening (e.g., 226), through which a fluid passes; (II) a valve seat portion (e.g., 122) having an opening (e.g., 212) at its bottom through which the fluid passes, said valve seat portion being fitted in inside the lower opening of the cylindrical support; and (III) a resinous valve portion comprising: (i) a valve body (e.g., 212) having a shape corresponding to the opening of the valve seat; and (ii) multiple connectors (e.g., 213) connecting the valve body to an inner wall (e.g., 201′) of the cylindrical support, said connectors elastically urging the valve body downward to close the opening and being bendable as the valve body moves upward.
In the above, the valve mechanism may include, but is not limited to, the following configurations:
The connectors may comprise at least three coupling portions (e.g., 213). The coupling portions may have flections (e.g., 214). Each of the valve seat portion and the valve portion may be formed with a single integrated piece made of a resin (e.g., 80, 122).
Another aspect of the present invention is a tube-type fluid container comprising a container body (e.g., 140, 1140) for storing a fluid having a mouth portion (e.g., 141, 1141), and any of the foregoing valve mechanisms (any suitable combination of elements thereof) attached to the mouth portion.
In the above, the container body may be a double wall container body (e.g., 1140) comprised of an inner container (e.g., 1142) for storing a fluid and an outer container (e.g., 1143), said inner container being flexible and compressible, said outer container having at least one through-hole (e.g., 1149, 1149′) for keeping an interior space between the inner container and the outer container at ambient pressure. The through-hole (e.g., 1149′) may have a size which can let a small amount of air through. The through-hole (e.g., 1149) may be formed in a portion to which a pressure is applied when the fluid is discharged. The inner container and the outer container are integrated at the mouth portion (e.g., 1148), and welded at their bottoms (e.g., 1147).
According to any of the foregoing valve mechanisms, a fluid can be closed reliably although its configuration is simple; a flow rate of the fluid passing through the valve mechanism can be changed discretionally according to a pressure applied to the valve mechanism. When using three or more connectors, the occurrence of an inadequate tilt in the valve body can effectively be prevented. When configuring the connectors to be substantially in contact with an inner wall of the valve seat portion, it becomes possible to more reliably prevent an inadequate tilt in the valve body from occurring. When forming flections in the connectors, the connectors have an adequate elasticity recovering force, moving the valve body satisfactorily between a closed position and an open position becomes possible. When using the guide mechanism which guides the valve body's movement from the closed position to the open position, it becomes possible to further reliably prevent an inadequate tilt in the valve body from occurring. When configuring the valve seat to be a separate piece from the cylindrical support and be fitted in the lower opening of the cylindrical support, and/or when forming the valve body, the connectors, and the cylindrical support as an integrated single piece, influence by plastic deformation caused during manufacturing processes (e.g., inflation molding) can be reduced, improving sealability between the valve body and the valve seat and improving assembly operation.
In the above, the fluid can be discharged from an outlet of the mouth portion of the container through the valve mechanism by pressing the container, wherein the connectors and the container are deformed. When releasing the pressure, both the deformed connectors and the deformed container begin restoring the shapes. The restoring force of the container causes the inner pressure to lower, thereby generating reverse flow which facilitates restoration of the connectors to close the opening of the valve seat portion, thereby effectively preventing air from coming into the container through the outlet of the mouth portion. Thus, even if the restoring force of the connectors themselves is not sufficient to close the opening of the valve seat portion, the outlet of the mouth portion can effectively be closed in combination with the restoring force of the container. Thus, even if the fluid is very viscous, the valve mechanism in combination with the container can discharge the fluid and then seal the container.
In the above, in the event that the restoring force of the container is excessive (depending on the viscosity of the fluid and the amount of the fluid remaining in the container, etc., in addition to the elasticity characteristics of the container itself), the reverse flow is strong and fast, and the connectors may not be restored so quickly that it is difficult to prevent air from coming into the container from the outlet of the mouth portion through the opening of the valve seat portion. In that case, by using a double wall container, the restoring force can be controlled so that intensity of the reverse flow can be controlled to prevent air from coming into the container.
That is, when configuring the container body to be a double wall container, despite its simple configuration, reverse flow of air from the discharge port (or the mouth) of the container into the container can be prevented and the content can be discharged easily even when an amount of the content is reduced. When forming the through-hole in the outer container in a size which can let a small amount of air through, an amount of air outflow from the inner container to the outside can be controlled to be small, enabling to apply appropriate pressure to the fluid inside the inner container because certain pressure between the inner container and the outer container can be maintained when the outer container is pressed. Wen forming the through-hole in a portion to which a pressure is applied when the fluid is discharged, an amount of air outflow from the inner container to the outside can be controlled to be small when the outer container is pressed, enabling to apply an appropriate pressure to the fluid inside the inner container. When integrating the inner container and the outer container at the mouth portion and welding them at their bottom, manufacturing a tube-type fluid container at low costs becomes possible.
Additionally, in a double wall container, restoring force of an inner container may be lower than that of a single wall container, and thus, after connectors are at a closed position, the pressure inside the inner container may remain moderately lower than the ambient pressure, so that suction force at the outlet may not be significant. In that case, it is possible to effectively prevent air from coming into the container. Further, in a double wall container, an outer container can be restored more than an inner container, and an air layer is formed between the inner container and the outer container. When restricting the flow of air released from the air layer through a through-hole or though-holes, it is possible to exert pressure on the inner container from the outer container via the air layer. Thus, even if the amount of the fluid contained in the inner container is low and thus, the inner container is nearly flat, by pressing the outer container which has been restored to the original shape, it is possible to exert pressure onto the inner container, thereby easily discharging the fluid. Accordingly, waste of the fluid remaining inside the inner container can be minimized.
For purposes of summarizing the invention and the advantages achieved over the related art, certain objects and advantages of the invention have been described above. Of course, it is to be understood that not necessarily all such objects or advantages may be achieved in accordance with any particular embodiment of the invention. Thus, for example, those skilled in the art will recognize that the invention may be embodied or carried out in a manner that achieves or optimizes one advantage or group of advantages as taught herein without necessarily achieving other objects or advantages as may be taught or suggested herein.
Further aspects, features and advantages of this invention will become apparent from the detailed description of the preferred embodiments which follow.
These and other features of this invention will now be described with reference to the drawings of preferred embodiments which are intended to illustrate and not to limit the invention.
Explanation of symbols used is as follows: 10: Valve portion; 11: Supporting portion; 12: Valve body; 13: Coupling portion; 14: Flections; 15: Concave portion; 16: Guide material; 17: Supporting portion; 18: Coupling portion; 19: Hole portion for guiding; 20: Valve seat portion; 23: Opening portion; 24: Protruding portion; 26: Opening portion; 29: Guide pin; 30: Valve portion; 40: Valve portion; 41: Supporting portion; 42: Valve body; 43: Coupling portion; 44: Flections; 50: Valve portion; 51: Supporting portion; 52: Valve body; 53: Coupling portion; 54: Flections; 60: Valve portion; 61: Supporting portion; 62: Valve body; 63: Coupling portion; 64: Flection; 70: Valve portion; 71: Supporting portion; 72: Valve body; 73: Coupling portion; 76: Coupling material; 77: Guide plate; 110: Lid material; 111: Lid portion; 112: Lid body; 113: Opening portion; 114: Closed portion; 115: Female screw portion; 140: Container main unit; 141: Opening portion; 142: Fluid storing portion; 143: Flange portion; 144: Male screw portion; 1140: Container main unit; 1141: Discharge port; 1142: Internal container; 1143: External container; 1144: Internal space; 1145: Internal container opening portion; 1146: External container opening portion; 1147: Welding portion on the bottom side; 1148: Welding portion on the discharge port side; 1149: Hole.
Preferred embodiments of the present invention will be described with referent to the drawings. The present invention is not limited to the embodiments.
This tube-type container may be used as a container for any suitable fluid including beauty products for storing gels such as hair gels and cleansing gels or creams such as nourishing creams and cold creams used in the cosmetic field. This tube-type container also can be used as a container for medicines, solvents or foods, etc.
In this specification, high-viscosity liquids, semifluids, gels that sol solidifies to a jelly, and creams, and regular liquids, are all referred to as fluids. The present invention, however, is not limited to a valve mechanism used for the above-mentioned fluids and can apply to a valve mechanism used for the entire fluids including gases.
This tube-type container comprises a container main unit 140, a lid material 110 placed at the top of the container main unit 140, and a valve portion 10 and a valve seat portion 20 comprising a valve mechanism.
The container main unit 140 comprises a fluid storing portion 142 for storing a fluid inside it, an opening portion 141 for discharging the fluid, which is formed at one end of the fluid storing portion 142, a flange portion 143 formed in the vicinity of the upper end of the opening portion 141, and a male screw portion 144 formed outside the opening portion 141. The flange portion 143 can engage with an engaging groove 21 in the valve seat portion 20, which is described later in detail. For this purpose, the valve seat portion 20 has a configuration in which it is fixed inside the opening portion 141 in the container main unit 140 via this engaging groove 21.
The container main unit 140 comprises synthetic resin alone or a lamination of synthetic resin and aluminum, and has an elasticity recovering force which tries to recover its original shape when a pressure applied to it is removed.
The above-mentioned lid material 110 comprises a base portion 111 at the center of which an opening portion 113 (See
In the a tube-type container having the above-mentioned configuration, when a fluid is discharged from the container, a pressure is applied to the fluid inside the fluid storing portion 142 by pressing the fluid storing portion 142 in the container main unit 140. In this position, the valve mechanism comprising the valve portion 10 and the valve seat portion 20 is opened; the fluid inside the fluid storing portion 142 is discharged outward via the opening portion 113 in the lid material 110 as shown in
After a necessary amount of the fluid is discharged and when the pressure applied to the fluid storing portion 142 is removed, the fluid inside the fluid storing portion 142 is depressurized by the elasticity recovering force of the container main unit 140 and the air tries to flow back toward the fluid storing portion 142 from the opening portion 141 used for discharging the fluid.
In this tube-type container, however, by the action of the valve mechanism comprising the valve portion 10 and the valve seating portion 20, a path in which the fluid passes through is closed. Consequently, reverse air flow can be effectively prevented.
In the above-mentioned embodiment, the lid material 110 comprising the base portion 111 at the center of which the opening portion 113 is formed and the lid body 112 at the bottom center of which the closed portion 114 is formed, is used. It is possible to use a lid material having a configuration in which the base portion 111 and the lid body 112 are integrated and the entire lid material is detached from the container main unit 140 when the fluid is discharged.
A configuration of the valve mechanism according to the present invention is described below.
As shown by these views, the valve seat portion 20 has a nearly tubular shape, at the bottom of which a circular opening portion 23 functioning as a valve seat is formed. Upward inside this valve seat portion 20, a pair of protruding portions 24 are formed.
The valve portion 10 has a ring-shaped supporting portion 11 which is arranged inside the valve portion 20, a valve body 12 having a shape corresponding to the circular opening portion 23 in the valve seat portion 20, and four coupling portions 13 which couple the supporting portion 11 and the valve body 12. The four coupling portions 13 have a pair of flections 14 respectively. In the valve portion 10, the valve body 12 is constructed in such a way that it can move between the closed position in which the valve body 12 closes the opening portion 23 in the valve seat portion 20 and the open position in which the valve body opens the opening portion 23 by the flexibility of the four coupling portion 13.
On an outer circumferential surface of the supporting portion 11 in the valve portion 10, a pair of concave portions 15 is formed. Consequently, when this valve portion 10 is inserted into the valve seat portion 20, as shown in
In a valve mechanism having this configuration, when a pressure is applied to a fluid inside the fluid storing portion 142 by pressing the fluid storing portion 142 of the container main unit 140 shown in
In the above, when the valve body 12 is moved upward to open the opening portion 23, the coupling portion 13 moves outward toward an inner wall 201 (e.g., in a radial direction or in a direction of drawing an arc), and the coupling portion 13 may be substantially or completely in contact with the inner wall 201 at a point 101 when moving outward and may restrict a further upward movement of the valve body 12 (avoiding unbalanced movement) even if the fluid flow is excessive. In the figure, the coupling portion 13 appears to be in contact with the inner wall. However, the coupling portion 13 needs not be in contact with the inner and is not in contact with the inner wall when the fluid flow through the opening portion 23 is not high. The above configuration is equally applicable to
In this valve mechanism, a traveling distance of the valve body 12 changes according to a pressure applied to the fluid storing portion 142, i.e. a pressure applied to the valve mechanism, changing a flow rate of the fluid passing through the opening portion 23 discretionally becomes possible.
In this valve mechanism, the supporting portion 11 in the valve portion 10 and the valve body 12 are coupled by the four coupling portions 13. Consequently, preventing occurrence of an inadequate tilt in the valve body 12 becomes possible. Additionally, to effectively prevent occurrence of an inadequate tilt in the valve body 12, it is preferred to provide three or more coupling portions 13 and to arrange them equally.
In this valve mechanism, when the valve body 12 moves from the closed position to the open position, the coupling portions 13 move in the direction in which they contact the inner walls of the valve seat portion 20. Consequently, when an inadequate tilt occurs in the valve body 12, the coupling portions 13 contact the inner walls of the valve seat portion 20, preventing the valve body 12 from tilting further.
Further, in this valve mechanism, the four coupling portions 13 coupling the supporting portion 11 and the valve body 12 have a pair of flections 14 respectively. Consequently, these coupling portions 13 have appropriate elasticity, enabling the valve body 12 to reciprocate smoothly between the closed position and the open position.
It is preferred that a thickness of these coupling portions 13 is 1 mm or less; a thickness within the ranger of 0.3 mm to 0.5 mm is more preferable. Additionally, a relation between a pressure applied to the fluid inside the fluid storing portion 142 and a discharge amount of the fluid can be adjusted by changing a thickness, a vertical length or a material (hardness) of the coupling portions 13. Or, the relation between a pressure applied to the fluid inside the fluid storing portion 142 and a discharge amount of the fluid also can be adjusted by changing an elastic force by the coupling portions 13 by changing a thickness or a width of the edge portion on the supporting portion 11 side of the coupling portions 13.
A configuration of the valve mechanism according to Embodiment 2 of the present invention is described below.
The valve mechanism according to Embodiment 2 differs from Embodiment 1 in comprising a guide mechanism for guiding a movement of the valve body 12 from a closed position to an open position to prevent occurrence of an inadequate tilt of the valve body 12 reliably. Additionally, when the same materials are used in this embodiment as those used in Embodiment 1, the same symbols are used and detailed descriptions of the materials are omitted.
In other words, in the valve mechanism according to Embodiment 2, a guide pin 29 is set up by standing it on the top of the valve body 12 in the valve portion 30. A guide material 16 is set up at an inner position of a supporting portion 11 in the valve portion 30. The guide material 16 comprises a ring-shaped supporting portion 17, three coupling portions 18 and a hole portion for guiding 19, which encircles the guide pin 29 from its circumferential portion.
In the valve mechanism according to Embodiment 2, when the valve body 12 moves from the closed position to the open position, occurrence of an inadequate tilt of the valve body 12 is able to be prevented because the guide pin 29, which is provided by standing it in the valve body 12, is guided by the guiding hole portion 19 of the guiding material 16. Additionally, as in this Embodiment 2, when the guide mechanism which guides a movement of the valve body 12 from its closed position to its open position is provided, the number of the coupling portions 13 can be two.
A configuration of the valve mechanism according to Embodiment 3 is described below.
In the valve mechanism according to this Embodiment 3, bending directions of flections 44 in four coupling portions 43 differ from bending directions of the flections 14 in the coupling materials 13 in the above-mentioned Embodiments 1 and 2. Additionally, when the same materials are used in this embodiment as those used in Embodiments 1 and 2, the same symbols are used and detailed descriptions of the materials are omitted.
The valve seat portion 20 of the valve mechanism according to Embodiment 3 has a valve seat portion having a nearly tubular shape, at the bottom of which a circular opening portion 26 which functions as a valve seat is formed. Upward inside this valve seat portion 20, a concave portion 25 is formed.
The valve portion 40 has a ring-shaped supporting portion 41 provided inside the valve seat portion 20, a valve body 42 having a shape corresponding to the circular opening portion 26 in the valve portion 20, and four coupling portions 43, which couple the supporting portion 41 and the valve body 42. The four coupling portions 43 have a pair of flections 44 respectively. In this valve portion 40, the valve body 42 is constructed in such a way that the valve body 42 can move between a closed position in which the valve body closes the opening portion 26 in the valve seat portion 20 and an open position in which the valve body opens the opening portion 26 by the flexibility of the four coupling portions 43.
As shown in
In the valve mechanism having this configuration, when a pressure is applied to a fluid inside the fluid storing portion 142 by pressing the fluid storing portion 142 of the container main unit 140 shown in
In this valve mechanism, a traveling distance of the valve body 42 changes according to a pressure applied to the fluid storing portion 142, i.e. a pressure applied to the valve mechanism, changing a flow rate of the fluid passing through the opening portion 26 discretionally becomes possible.
In this valve mechanism, in the same manner as in the valve mechanism according to Embodiments 1 and 2, when the valve body 42 moves from the closed position to the open position, the coupling portions 43 move in the direction in which they contact the inner walls of the valve seat portion 20. Consequently, when an inadequate tilt occurs in the valve body 42, the coupling portions 43 contact the inner walls of the valve seat portion 20, preventing the valve body 42 from tilting further.
Further, in this valve mechanism, four coupling portions 43 coupling the supporting portion 41 and the valve body 42 have a pair of flections 44 respectively. Consequently, these coupling portions 43 have appropriate elasticity, enabling the valve body 42 to reciprocate smoothly between the closed position and the open position.
A configuration of the valve mechanism according to Embodiment 4 is described below.
While the four coupling portions 43 couple the supporting portion 41 and the valve body 42 in the above-mentioned Embodiment 3, three coupling portions 53 couple the supporting portion 51 and the valve body 52 in Embodiment 4. Additionally, when the same materials are used in this embodiment as those used in Embodiment 3, the same symbols are used and detailed descriptions of the materials are omitted.
In the valve mechanism according to this Embodiment 4, the valve portion 50 has the ring-shaped supporting portion 51 provided inside the valve seat portion 20, the valve body 52 having a shape corresponding to the circular opening portion 26 in the valve portion 20, and the three coupling portions 53, which couple the supporting portion 51 and the valve body 52. The three coupling portions 53 have a pair of flections 54 respectively. These pairs of flections 54 have different bending directions respectively. In this valve portion 50, the valve body 52 is constructed in such a way that the valve body 52 can move between a closed position in which the valve body closes the opening portion 26 in the valve seat portion 20 and an open position in which the valve body opens the opening portion 26 by the flexibility of the three coupling portions 53.
As shown in
In the valve mechanism having this configuration, when a pressure is applied to a fluid inside the fluid storing portion 142 by pressing the fluid storing portion 142 of the container main unit 140 shown in
In this valve mechanism, a traveling distance of the valve body 52 changes according to a pressure applied to the fluid storing portion 142, i.e. a pressure applied to the valve mechanism, changing a flow rate of the fluid passing through the opening portion 26 discretionally becomes possible.
In this valve mechanism, in the same manner as in the valve mechanism according to Embodiments 1, 2, and 3 when the valve body 52 moves from the closed position to the open position, the coupling portions 53 move in the direction in which they contact the inner walls of the valve seat portion 20. Consequently, when an inadequate tilt occurs in the valve body 52, the coupling portions 53 contact the inner walls of the valve seat portion 20, preventing the valve body 52 from tilting further.
Further, in this valve mechanism, the three coupling portions 53 coupling the supporting portion 51 and the valve body 52 have a pair of flections 54 respectively. Consequently, these coupling portions 53 have appropriate elasticity, enabling the valve body 52 to reciprocate smoothly between the closed position and the open position.
A configuration of the valve mechanism according to Embodiment 5 is described below.
While respective coupling portions 13, 43 and 53 in the above-mentioned Embodiments 1 to 4 have multiple flections 14, 44 and 54, respective coupling portions have a single flection 64 in the valve mechanism according to Embodiment 5.
In this valve mechanism, in the same manner as in the valve mechanism according to Embodiments 1 to 4, when the valve body 62 moves from a closed position to an open position, the coupling portions 63 move in the direction in which they contact the inner walls of the valve seat portion 20. Consequently, when an inadequate tilt occurs in the valve body 62, the coupling portions 63 contact the inner walls of the valve seat portion 20, preventing the valve body 62 from tilting further.
Because the motion of the valve mechanism according to Embodiment 5 is the same as that of the valve mechanisms according to Embodiments 1 to 4, the detailed description for the motion is omitted.
A configuration of the valve mechanism according to Embodiment 6 is described below.
The valve portion 70 in the valve mechanism according to Embodiment 6 has a ring-shaped supporting portion 71 provided inside the valve seat portion 20, a valve body 72 having a shape corresponding to the circular opening portion 23 in the valve portion 20, and four coupling portions 73, which couple the supporting portion 71 and the valve body 72. In this valve portion 70, the valve body 72 is constructed in such a way that the valve body 72 can move between a closed position in which the valve body closes the opening portion 23 in the valve seat portion 20 and an open position in which the valve body opens the opening portion 23 by the flexibility of the four coupling portions 73.
As shown in
In the valve mechanism having this configuration, when a pressure is applied to a fluid inside the fluid storing portion 142 by pressing the fluid storing portion 142 of the container main unit 140 shown in
In this valve mechanism, a traveling distance of the valve body 72 changes according to a pressure applied to the fluid storing portion 142, i.e. a pressure applied to the valve mechanism, changing a flow rate of the fluid passing through the opening portion 23 discretionally becomes possible.
In this valve mechanism, in the same manner as in the valve mechanism according to Embodiments 1 and 5, when the valve body 72 moves from the closed position to the open position, the coupling portions 73 move in the direction in which they contact the inner walls of the valve seat portion 20. Consequently, when an inadequate tilt occurs in the valve body 72, the coupling portions 73 contact the inner walls of the valve seat portion 20, preventing the valve body 72 from tilting further.
In this valve mechanism, a coupling material 76 is set up by standing it above the valve body 72; on the upper end of this coupling material 76, a guide plate 77 is provided. An outside diameter of this guide plate 77 is slightly smaller than an inside diameter of the supporting portion 71. Because of this, when an inadequate tilt occurs in the valve body 72, the guide plate 77 contacts the inner walls of the valve seat portion 20, preventing further tilting of the valve body 72. This enables to prevent occurrence of an inadequate tilt in the valve body 72 more reliably.
When this guide mechanism comprising the coupling material 76 and the guide plate 77 is provided, it is not necessary to adopt a configuration in which the coupling portions 73 moves in the direction of contacting inner walls of the valve seat portion 20 when the valve body 72 moves from the closed position to the open position.
In this valve mechanism according to Embodiment 7, as four coupling portions 79 coupling the supporting portion 71 in the valve portion 70, a configuration, in which the coupling portions 79 move in the direction-separating from the inner walls of the valve seat portion 20 when the valve body 72 moves from the closed position to the open position, is adopted. Even when this configuration is adopted, by the action of a guide mechanism comprising the coupling material 76 and the guide plate 77, occurrence of an inadequate tilt in the valve body 72 can be prevented.
Additionally, in respective embodiments mentioned above, the modes in which the valve mechanism according to the present invention applies to tube-type fluid containers were described. The present invention, however, also can be applied to, for example, fluid discharge pumps used for fluid storing containers, etc.
Furthermore, in respective embodiments mentioned above, the present invention is applied to the valve mechanism used for fluids. The present invention, however, can be applied to the valve mechanism used for gases. In this case, as a material for respective coupling portions 13, 43, 53, 63, 73 and 79, a material with high rigidity is used so that stronger momentum is given to respective valve bodies 12, 42, 52, 62 and 72 in the direction of the opening portions 23 and 26.
When configuring the valve seat to be a separate piece from the cylindrical support and be fitted in the lower opening of the cylindrical support, and/or when forming the valve body, the connectors, and the cylindrical support as an integrated single piece, influence by plastic deformation caused during manufacturing processes (e.g., inflation molding) can be reduced, improving sealability between the valve body and the valve seat and improving assembly operation.
The closing and opening operation is the same as in the previous embodiments. Although this embodiment does not show connectors which are in contact with an inner wall of the cylindrical support, such connectors can be used as in the previous embodiments. Thus, the connectors may comprise at least three coupling portions, and may have flections.
Another preferred embodiment of the present invention is described with referent to the drawings.
This tube-type container is used as a container for beauty products for storing gels such as hair gels and cleansing gels or creams such as nourishing creams and cold creams used in the cosmetic field. Additionally, this tube-type container also can be used as a container for medicines, solvents or foods, etc.
This tube-type container possesses a container main unit 1140, a lid material 110 which is placed at the top of the container main unit 1140, and a valve mechanism 10′.
A configuration of the container main unit 1140 of the tube-type fluid container according to Embodiment 9 of the present invention is described below.
The container main unit 1140 possesses an internal container 1142 storing a fluid and an external container 1143 encompassing the internal container 1142. An internal space 1144 which is shut off from the outside is formed between the internal container 1142 and the external container 1143.
The external container 1143 in this container main unit 1140 has a configuration comprising synthetic resin alone or a lamination of synthetic resin and aluminum, and has an elasticity recovering force which tries to recover its original shape when a pressure applied to it is removed. Further, in the external container 1143, a hole 1149′ which communicates with the interior space and the outside is formed. This hole 1149′ formed in the external container has a size (including 0.1–3 mm, 0.5–2 mm) which can let a small amount of air through. One or more holes 1149′ can be formed (including 2, 3, or 4 holes).
When a pressure is applied to the container main unit 1140 from the position shown in
Because this hole 1149′ has a size which can let a slight amount of the air through, an outflow of the air from the internal space 1144 to the outside can be controlled to be small. Consequently, it becomes possible to apply a right pressure to the fluid inside the internal container 1142.
The internal container 1142 and the external container 1143 are both formed/shaped by blow molding, and then an opening portion 1145 of the internal container and an opening portion 1146 of the external container are connected each other at the welding portion 1148 on the discharge port side of the container main unit 1140 and are welded at a welding portion 1147 on the bottom side. Consequently, it becomes possible to manufacture tube-type fluid containers at low costs.
The tube-type fluid container according to Embodiment 10 of the present invention is described below.
This tube-type fluid container, in the same way as that according to Embodiment 9, possesses an internal container 1142 storing a fluid and an external container 1143 encompassing the internal container 1142. An internal space 1144 which is shut off from the outside is formed between the internal container 1142 and the external container 1143; in the external container 1143, a hole 1149 which communicates with the interior space and the outside is formed.
The hole 1149 formed in the external container 1143 at a pressing portion in the external container 1143, to which a pressure is applied when a fluid is pushed out. With this configuration, when the external container 1143 in the container main unit 1140 is pressed, a good part of the hole 1149 is blocked off, for example, by a pressing object such as a finger; an outflow of the air to the outside from the internal space can be controlled to be small; it becomes possible to apply a right pressure to the fluid inside the internal container 1142. The hole 1149 is larger than the hole 1149′ in the previous embodiment (e.g., a diameter of 2–10 mm, 3–5 mm). One or more holes 1149 can be formed.
Because a size of the hole 1149 should be within the range not exceeding a size of the pressing object, a large amount of the air enters the internal space when the pressing object separates from the pressing portion. By this, the external container 1143 can quickly restore its original shape.
Additionally, the valve mechanism applied to the tube-type fluid container according to the present invention is not limited to the valve mechanisms 10 according to respective embodiments described above, but can be applied to any valve mechanisms in which an opening portion is opened when the container main unit 1140 is pressed and the opening portion is closed when a pressure applied to the container main unit 1140 is removed.
Additionally, for the external container 1143, a material with an elasticity recovering force needs to be used. For the internal container 1142, a material without an elasticity recovering force can be used.
In the above-mentioned embodiment, a configuration in which the opening portions of the internal container 1145 and of the external container 1146 are connected each other at a welding portion 1148 on the discharge port portion side of the container main unit, and the internal container and the external container are welded at their bottoms is adopted. A different configuration, in which the container main unit 1140 comprising three parts, a discharge port material having the male screw portion 151, the internal container 1142 and the external container 1143, and the opening portions of the internal container 1145 and of the external container 1146 are respectively welded to the discharge port material, can also be adopted.
In the present invention, any suitable plastic material can be used including rubbers such as silicon rubbers or soft resins such as soft polyethylene. For support portions (such as the valve seat portion) to which other portions (such as the valve portion) are fitted by press-fitting, hard resins such as hard polyethylene can preferably be used. The structures can be formed by any suitable methods including injection molding.
Various embodiments of valve mechanisms have been described above. However, the present invention is not limited to particular structures depicted in the drawings. Any suitable or feasible combinations of elements can be accomplished, and the present invention includes the following: That is, the present invention can also be characterized in that a valve mechanism comprises: (i) a valve seat portion having a nearly tubular shape, at the bottom of which a circular opening portion which functions as a valve seat is formed, (ii) a ring-shaped supporting portion which is arranged inside the valve seat portion, (iii) a valve body having a shape corresponding to the circular opening portion, and (iv) multiple coupling portions which couple the supporting portion and the valve body, wherein a resinous valve portion is constructed in such a way that the valve body can move between a closed position in which the valve body closes the opening portion in the valve seat portion and an open position in which the valve body opens the opening portion by the flexibility of the multiple coupling portions.
It will be understood by those of skill in the art that numerous and various modifications can be made without departing from the spirit of the present invention. Therefore, it should be clearly understood that the forms of the present invention are illustrative only and are not intended to limit the scope of the present invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2002-168208 | Jun 2002 | JP | national |
| 2002-198089 | Jul 2002 | JP | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 2715980 | Frick | Aug 1955 | A |
| 2755974 | Godfrey | Jul 1956 | A |
| 2777612 | Bensen | Jan 1957 | A |
| 3165242 | Jackson | Jan 1965 | A |
| 3456650 | Schwartzman | Jul 1969 | A |
| 3490658 | Schwartzman | Jan 1970 | A |
| 3506162 | Schwartzman | Apr 1970 | A |
| 3945540 | Mantchev | Mar 1976 | A |
| 4597511 | Licari | Jul 1986 | A |
| 4785978 | Kano et al. | Nov 1988 | A |
| 5152434 | Birmelin | Oct 1992 | A |
| 5275312 | Labruzzo | Jan 1994 | A |
| 5819990 | Cimentepe et al. | Oct 1998 | A |
| 5842618 | Julemont et al. | Dec 1998 | A |
| Number | Date | Country |
|---|---|---|
| 4329808 | Mar 1995 | DE |
| 0 537 822 | Apr 1993 | EP |
| 1 291 288 | Mar 2003 | EP |
| 1 433 142 | Mar 1966 | FR |
| 2 732 315 | Oct 1996 | FR |
| 2 828 679 | Feb 2003 | FR |
| U 59-26748 | Feb 1984 | JP |
| 07-112749 | May 1995 | JP |
| 08-026311 | Jan 1996 | JP |
| 08-034452 | Feb 1996 | JP |
| 09 240701 | Sep 1997 | JP |
| 10-157751 | Jun 1998 | JP |
| 2001 240089 | Sep 2001 | JP |
| 20-0241101 | Jul 2001 | KR |
| WO 8901104 | Feb 1989 | WO |
| WO 9510965 | Apr 1995 | WO |
| WO 0222458 | Mar 2002 | WO |
| Number | Date | Country | |
|---|---|---|---|
| 20030230596 A1 | Dec 2003 | US |
