Cap device for mixing different kinds of materials separately contained therein and in bottle

Abstract

A cap device for bottles allows an additive and a material to be separately stored in the cap device and a bottle, thus preventing the additive from being undesirably added to the bottled material. Furthermore, the cap device may contain a semisolid additive therein, as desired, thus allowing a user to mix the semisolid additive with the bottled material to prepare a mixture. The cap device has a cap body tightened to a mouth or an open lower end of the bottle, with an additive discharging means provided in the cap body to discharge the additive from a space inside the cap body into the bottle. The cap device further has a valve means for opening or closing the discharging means, according to a rotating action of the cap device relative to the bottle. The valve means includes a valve part which is brought into close contact with or spaced apart from the discharging means, thus closing or opening the discharging means to allow the additive to be discharged into the bottle to prepare the mixture. The valve means further includes a plurality of radial or vertical ribs which are integrated with the valve part into a single structure.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates, in general, to caps for bottles which contain therein a variety of materials, such as drinks, liquid medicines or liquid chemicals. More particularly, the present invention relates to a cap device for such bottles, which is capable of mixing an additive contained within the cap device with a bottled material to prepare a mixture according to a simple rotating action of the cap device relative to a bottle, thus allowing a user to easily prepare the mixture just before drinking or using the mixture.

2. Description of the Related Art

In the related art, most of conventional disposable bottles circulated and sold in markets each contain therein only a single kind of material, such as a drink, a liquid medicine or a liquid chemical, and are closed by caps at mouths thereof. When a user wants to add an additive to the material contained in such a capped bottle so as to prepare a mixture prior to drinking or using the mixture, the user must add the additive from a separate container to the bottled material after removing a cap from the bottle. Therefore, it is necessary for manufacturers of the additives and the bottled materials to contain such additives and materials in separate containers and bottles prior to marketing them, thus undesirably wasting natural resources due to the production of the separate containers and capped bottles. In addition, the adding of the additive from the separate container to the bottled material to mix them after removing the cap from the bottle is inconvenient to the user in that the user is forced to separately purchase and handle the additive container and the bottle.

Furthermore, it is extremely difficult for the user to add a precise amount of the additive from the separate container to the material contained in the bottle, and thus, the user roughly measures the amount of the additive to be added to the bottled material. Therefore, in the case of mixing of an additive with a bottled drink to produce a mixed beverage, the rough measurement of the amount of the additive may result in change in taste and quality of the mixed beverage. In the case of mixing of an additive with a bottled liquid medicine or a bottled liquid chemical to produce a mixed medicine or a mixed chemical, the rough measurement of the amount of the additive may result in incomplete dissolution of effective ingredients of the additive in the medicine or the chemical and a failure of accomplishment of desired medical or chemical effects of the mixed medicine or the mixed chemical.

Of course, when mixtures are prepared by manufacturers at factories and are marketed in a bottled state, in place of allowing users to mix additives with bottled materials to prepare mixtures just before drinking or using the mixtures, it is possible to avoid the above-described problems experienced in the mixing of the additives with the bottled materials performed by the users. However, the mixtures which are prepared by the manufacturers and marketed in the bottled state are problematic in that the effects of ingredients of the bottled mixtures may be gradually degraded as time goes by, in addition to change in colors of the mixtures. Furthermore, the bottled mixtures may generate floating matters and deposit therein with passage of time.

In an effort to overcome the above-described problems, the inventor of the present invention proposed a cap device for bottles, which is capable of mixing an additive contained therein with a material contained in a bottle to prepare a mixture, in Korean Patent Application No. 10-2002-31470. In the above cap device disclosed in Korean Patent Application No. 10-2002-31470, a plurality of radial ribs are provided at a valve means, and are supported at outside ends thereof on an inner surface of a neck of the bottle. However, since the outside ends of the above radial ribs are formed as free ends, the radial ribs may be easily bent or deformed. Therefore, the valve means may be easily displaced in the neck of the bottle.

Furthermore, it is necessary to separately store the additive in the cap device and the material in the bottle so that the additive is not undesirably added to the bottled material. Therefore, a sealing means for allowing the additive and the material to be separately stored in the cap device and the bottle is required.

That is, it is necessary to accomplish an airtight or watertight sealing effect at a junction between a part of the cap device containing the additive therein and another part of the cap device which communicates with the bottle containing the material therein, thus preventing an undesired premature mixing of the additive with the bottled material and thereby preventing any physical or chemical change in the additive and the bottled material due to the undesired premature mixing of them. When the airtight or watertight sealing effect at the above junction is accomplished, the operational effect of the cap device is enhanced.

SUMMARY OF THE INVENTION

Accordingly, the present invention has been made keeping in mind the above problems occurring in the related art, for example, Korean Patent Application No. 10-2002-31470, and it is an aspect of the present invention to provide a cap device for bottles, which is capable of mixing an additive contained therein with a bottled material to prepare a mixture according to a simple rotating action of the cap device relative to a bottle, performed by a user, thereby allowing the user to easily prepare the mixture just before drinking or using the mixture.

It is another aspect of the present invention to provide a cap device for bottles, in which a valve means is stably placed at a desired position in a neck of the bottle, without being undesirably displaced.

It is a further aspect of the present invention to provide a cap device for bottles, which allows the additive and the material to be separately stored in the cap device and the bottle, respectively, such that the additive is prevented from being prematurely added to the bottled material.

It is still another aspect of the present invention to provide a cap device for bottles, which contains a semisolid additive therein, and allows a user to mix the semisolid additive with a bottled material to prepare a mixture by simply rotating the cap device relative to a bottle just before drinking or using the mixture.

Additional aspects and/or advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

The above and/or other aspects are achieved by providing a cap device for bottles having a cap body tightened to a mouth of a bottle through screw-type engagement with a funnel part integrally formed in the cap body to discharge an additive from the cap body into the bottle through a lower end thereof. The cap device has a cap cover provided on the cap body to cover an open upper end of the cap body while defining a space inside both the cap body and the cap cover to contain the additive in the space. The cap device further has a valve means for opening or closing the lower end of the funnel part of the cap body according to a rotating action of the cap body relative to the externally threaded mouth of the bottle, wherein the valve means comprises a valve member having: a conical valve part to be brought into close contact with or spaced apart from the lower end of the funnel part of the cap body, thereby closing or opening the lower end of the funnel part, respectively. In addition, a plurality of radial ribs extending outward from an external surface of the conical valve part in radial directions, and a ring is integrated with the outside ends of the radial ribs for attachment to an inner surface of a neck of the bottle. In the alternative, the conical valve part can have an upwardly protruding shank having an external threading on its side surface corresponding to internal threading formed on the inner surface of the lower end of the funnel part.

In an alternative embodiment, the objects of this invention can be achieved by providing a cap device for bottles, comprising: a cap body tightened to a mouth of a bottle through screw-type engagement, the cap body being opened at an upper end thereof, with a cylindrical space defined in the cap body and valve means provided in the cap body at a lower end of the cylindrical space; an additive container having a space to contain an additive therein, the additive container being received in the cylindrical space of the cap body, with a discharging port provided on a lower end of the additive container to come in close contact with the valve means of the cap body, and an upper end of the additive container being opened and projected upward from the open upper end of the cap body; a cap cover tightened to the open upper end of the cap body through screw-type engagement; and a means for locking the cap cover to the upper end of the additive container.

In another alternative embodiment, the objects of this invention can be achieved by providing a cap device for bottles, comprising: a cap body tightened to a mouth of a bottle through screw-type engagement, the cap body being opened at an upper end thereof, with a cylindrical space defined in the cap body and valve means provided in the cap body at a lower end of the cylindrical space; an additive container having a space to contain an additive therein, the additive container being received in the cylindrical space of the cap body, with a discharging opening provided on a lower end of the additive container to come in close contact with the valve means of the cap body, and an upper end of the additive container being opened and projected upward from the open upper end of the cap body; a control unit assembled with the open upper end of the cap body to rotate relative to the cap body, with an internal thead provided on an inner circumferential surface of the control unit to be tightened to an outer circumferential surface of the upper end of the additive container through screw-type engagement, so that the control unit controls a vertical movement of the additive container; and a cap cover tightened to an upper end of the control unit.

Also, in another embodiment, the objects of this invention can be achieved by providing a cap device for bottles, comprising: a cap body tightened to an open lower end of a bottle through screw-type engagement, the cap body being opened at a lower end thereof, with a cylindrical space defined in the cap body and valve means provided in the cap body at an upper end of the cylindrical space; an additive container having a space to contain an additive therein, the additive container being received in the cylindrical space of the cap body, with a discharging opening provided on an upper end of the additive container to come in close contact with the valve means of the cap body, and a lower end of the additive container being opened and projected downward from the open lower end of the cap body; and a control unit having a cup shape which is closed at a bottom thereof, the control unit being assembled with the open lower end of the cap body to rotate relative to the cap body, with an internal thread provided on an inner circumferential surface of the control unit to be tightened to an outer circumferential surface of the lower end of the additive container through screw-type engagement, so that the control unit controls a vertical movement of the additive container.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other objects, features and other advantages of the present invention will be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings, in which:

FIG. 1 is an exploded perspective view showing a construction of a cap device, according to a first embodiment of the present invention;

FIG. 2 is a perspective view of the cap device of FIG. 1, when the assembled cap device is tightened to a mouth of a bottle;

FIGS. 3a and 3b are sectional views showing an operation of the cap device of FIG. 1;

FIG. 4a is a perspective view of a valve means of the cap device, according to a second embodiment of the present invention;

FIG. 4b is a sectional view showing an operation of the valve means of FIG. 4a, which is installed in the cap device tightened to a mouth of a bottle;

FIG. 5 is a perspective view of a cap device according to a third embodiment of the present invention, when the cap device is tightened to a mouth of a bottle;

FIG. 6 is a sectional view showing a construction of the cap device of FIG. 5;

FIGS. 7a, 7b and 7c are sectional views showing an operation of the cap device of FIG. 5;

FIG. 8 is an exploded perspective view of the cap device of FIG. 5;

FIG. 9 is a sectional view of a cap device according to a fourth embodiment of the present invention, when the cap device is tightened to a mouth of a bottle;

FIG. 10 is a sectional view of a cap device according to a fifth embodiment of the present invention, when the cap device is tightened to a mouth of a bottle;

FIG. 11 is a sectional view of a cap device according to a sixth embodiment of the present invention, when the cap device is tightened to a mouth of a bottle; and

FIG. 12 is a sectional view of a cap device according to a seventh embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Reference will now be made in detail to the present preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to like elements throughout. The embodiments are described below in order to explain the present invention by referring to the figures.

First Embodiment

FIGS. 1 through 3b are views of a cap device for bottles according to the first embodiment of the present invention. As shown in FIGS. 1 through 3b, the cap device according to the first embodiment of the present invention comprises a cap body 50, and a cap cover 100 provided on the cap body 50 to define a space therein to contain an additive in the space. The cap device further has a valve means to allow the space defined by both the cap body 50 and the cap cover 100 to selectively communicate with an interior of a bottle 13.

In a detailed description, the cap body 50 is tightened to an externally threaded mouth 12 of the bottle 13, with a funnel part 52 integrally formed in the cap body 50 to discharge the additive into the bottle 13 through a lower end thereof.

The cap cover 100 is provided on the cap body 50 to cover an open upper end of the cap body 50 while defining the space inside both the cap body 50 and the cap cover 100 to contain the additive in the space.

In the first embodiment of the present invention, the valve means comprises a valve member V having a conical valve part 14 acting as a valve seat to be brought into close contact with or spaced apart from the lower end of the funnel part 52 of the cap body 50. The conical valve part 14 of the valve member V thus closes or opens the lower end of the funnel part 52 according to the rotating action of the cap body 50 relative to the externally threaded mouth 12 of the bottle 13. A plurality of radial ribs 124 extend outward from an external surface of the conical valve part 14 in radial directions such that outside ends of the radial ribs 124 are supported on the inner surface of a neck of the bottle 13. In order to allow the outside ends of the radial ribs 124 to be stably supported on the inner surface of the neck of the bottle 13, a circular ring 24 having a predetermined thickness integrally surrounds the outside ends of the radial ribs 124.

When the cap body 50 of the cap device having the above-described construction is rotated to move up relative to the externally threaded mouth 12 of the bottle 13, the valve means separates from the lower end of the funnel part 52, thus, opening the lower end of the funnel part 52 of the cap body 50. Therefore, the space defined by the cap body 50 and the cap cover 100 of the cap device communicates with the interior of the bottle 13, as shown in FIGS. 3a and 3b. The additive is thus discharged from the space defined by the cap body 50 and the cap cover 100 into the bottle 13 to be mixed with a material contained in the bottle 13 to produce a mixture.

In the cap device of FIGS. 1, 2, 3a and 3b, a vacuum pressure may act on the surface of the additive contained in the space of the cap device, when the cap cover 100 is completely closed. In such a case, the additive cannot smoothly flow from the space of the cap device into the bottle 13, even when the space communicates with the interior of the bottle 13 by an operation of the valve means. In order to allow the additive to smoothly flow from the space into the bottle 13 in response to the communication of the space with the interior of the bottle 13, a small vent hole provided with a valve cock C to open or close the vent hole is formed at a top surface of the cap cover 100. When the valve cock C opens the vent hole, atmospheric air is introduced into the space of the cap device through the vent hole, thereby preventing any vacuum pressure from acting on the surface of the additive in the space. The additive thus smoothly flows from the space of the cap device into the bottle 13, so that the additive is easily added to the material in the bottle 13 to produce a desired mixture.

Second Embodiment

FIGS. 4a and 4b are views of a valve means of the cap device, according to the second embodiment of the present invention. As shown in FIGS. 4a and 4b, a sealing means is provided at a junction between the valve member V and the lower end of the funnel part 52 of the cap body 50, thus accomplishing an airtight or watertight sealing effect at the junction.

The sealing means is provided at the conical valve part 14 of the valve member V. That is, the sealing means comprises a plugging shank 14S of a conical valve body extending upward from a valve holder 14T of the valve part 14. An external thread is formed around the plugging shank 14S, such that the external thread of the plugging shank 14S has the same pitch as an internal thread of the lower end of the funnel part 52 of the cap body 50. In order to engage with the external thread of the plugging shank 14S, the lower end of the funnel part 52 is provided with an engaging part 52S on an internal surface thereof. Due to the sealing means, the desired sealing effect at the junction between the valve member V and the funnel part 52 is accomplished.

When the cap body 50 of the cap device is rotated to move up relative to the externally threaded mouth 12 of the bottle 13, the lower end of the funnel part 52 is rotated to move in the same direction relative to the plugging shank 14S. In such a case, the internal thread 52S of the funnel part 52 moves upward along the external thread of the plugging shank 14S to open the lower end of the funnel part 52. Due to the screw-type engagement of the valve member V with the lower end of the funnel part 52, it is possible to accomplish the airtight or watertight sealing effect at the junction between the valve member V and the lower end of the funnel part 52.

Third Embodiment

FIGS. 5 through 8 are views of a cap device according to a third embodiment of the present invention. As shown in FIGS. 5 through 8, the cap device according to the third embodiment of the present invention includes a cap body 100B, an additive container 50 and a cap cover 100A. The cap body 100B is tightened to an externally threaded mouth 10 of a bottle 13, and defines a cylindrical space 103 inside the mouth 10 when the cap body 100B is tightened to the mouth 10. The additive container 50 is received in the cylindrical space 103 of the cap body 100B and has a space 51 therein to contain an additive in the space 51. The cap cover 100A is tightened to an open upper end of the cap body 100B to cover the open upper end of the cap body 100B.

In a detailed description, the cap body 100B has a double-walled structure at a lower portion thereof, as shown in FIG. 6. The double-walled structure of the cap body 100B includes an outer sidewall 101 and an inner sidewall 102. The outer sidewall 101 has an internal thread on an inner circumferential surface thereof for engagement to externally threading formed on the mouth 10 of the bottle 13. The cylindrical space 103 is defined inside the inner sidewall 102 with a valve means 222 provided in the inner sidewall 102 of the cap body 100B at a lower end of the cylindrical space 103. As best seen in FIG. 6, the valve means 222 includes a plurality of radial ribs 222-1 which extend inward from the inner sidewall 102 of the cap body 100B in radial directions at the lower end of the cylindrical space 103. The valve means 222 further includes a circular valve part integrated with inside ends of the radial ribs 222-1. The circular valve part has both an annular groove part 222-2 and a dome part 222-3. The dome part 222-3 is provided on a central area of the valve part, while the annular groove part 222-2 is provided around the dome part 222-3. The annular groove part 222-2 is inclined upward and outward on an outside surface thereof, thus providing a first inclined surface. In this embodiment, the radial ribs 222-1, the annular groove part 222-2 and the dome part 222-3 are integrated with each other into a single structure. The circular valve part having the annular groove part 222-2 and the dome part 222-3 is brought into close contact with a flanged discharging port 52 of the container 50, as will be described in detail later herein, thus executing a valve function. When the valve part of the cap body 100B opens the flanged discharging port 52 of the container 50, the additive flows from the space 51 of the container 50 into the bottle 13 through a plurality of spaces defined between the radial ribs 222-1, thus being added to a bottled material to prepare a desired mixture.

The inner sidewall 102 of the cap body 100B is inserted into the mouth 10 of the bottle 13 when the cap body 100B is tightened to the mouth 10 of the bottle 13. The cap body 100B is also opened at the upper end thereof, thus having the open upper end 104. That is, the open upper end 104 of the cap body 100B is projected upward from the remaining part of the cap body 100B, and has an external thread on the outer circumferential surface thereof, with a plurality of air paths 105 (see FIG. 8) vertically provided on the externally threaded outer circumferential surface of the open upper end 104 of the cap body 100B. The air paths 105 guide atmospheric air to a vent hole H of the additive container 50, as will be described in detail later herein.

The additive container 50, which is a cylindrical body, is opened at the upper and lower ends thereof, as shown in FIG. 6. The additive container 50 has the flanged discharging port 52 at a bottom wall thereof. The flanged discharging port 52=is projected downward from the bottom wall of the container 50, and is inclined upward and inward on a lower end surface thereof, thus providing a second inclined surface, as best seen in FIG. 6. Thus, the flanged discharging port 52 is able to be in close contact with the annular groove 222-2 of the valve means 222 of the cap body 100B when the valve means 222 is closing the discharging port 52. In the above state, the flanged discharging port 52 is in linear contact with the annular groove 222-2 of the valve means 222, thus providing a higher contact pressure which prevents the additive from undesirably leaking from the container 50 into the bottle 13. The additive container 50 defines the space 51 therein to contain the additive in the space 51. The additive container 50 is also rounded along an inside corner of the bottom wall thereof, thus providing a rounded surface S on the inside corner of the bottom wall. Due to the rounded surface S, the additive is smoothly discharged from the space 51 of the container 50 into the bottle 13 through the flanged discharging port 52 in response to an operation of the valve means 222 to open the flanged discharging port 52.

The cap device of the third embodiment further includes a means for locking the cap cover 100A to the upper end of the additive container 50 while allowing the container 50 to move vertically, in conjunction with a rotation of the cap cover 100A. The locking means includes an outside locking part 53 that is provided around the outer circumferential surface of the upper end of the additive container 50. The locking means further includes an inside locking part 111 that is provided around the inner circumferential surface of the cap cover 100A to engage with the outside locking part 53 of the container 50. Thus, the additive container 50 is locked to the cap cover 100A by engagement of the outside locking part 53 with the inside locking part 111, so that the cap cover 100A is removed from the container 50 when the cap cover 100A is rotated with an external rotating force which is stronger than a predetermined reference force. In other words, when the cap cover 100A is rotated with an appropriate rotating force, the container 50 moves vertically in conjunction with the rotation of the cap cover 100A.

The additive container 50 has the vent hole H at a predetermined position on the upper portion of a sidewall thereof. When the cap cover 100A is fully tightened to the upper end 104 of the cap body 100B as shown in FIG. 6, the vent hole H of the container 50 is closed by the upper end 104 of the cap body 100B. However, when the cap cover 100A is loosened from the upper end 104 of the cap body 100B as shown in FIG. 7a, the upper portion of the container 50 having the vent hole H moves upward so that the vent hole H is exposed above the upper end 104 of the cap body 100B. In the above state, atmospheric air is guided into the container 50 via the air paths 105 (see FIG. 8) of the cap body 100B and the vent hole H of the container 50.

The cap device of the third embodiment further includes a stop protrusion 54. The stop protrusion 54 is an annular ring which is provided around the outer circumferential surface of the additive container 50 at an intermediate position. The stop protrusion 54 limits an upward movement of the additive container 50 within a predetermined range. That is, the stop protrusion 54 of the container 50 is stopped by the cap body 100A during the upward movement of the container 50, thus limiting the upward movement of the container 50 within the predetermined range. The provision of the stop protrusion 54 on the container 50 is to accomplish the following operational effect. That is, at a last stage of loosening the cap cover 100A from the cap body 100B, the stop protrusion 54 of the container 50 is stopped by the cap body 100A. In the above state, when the cap cover 100A is rotated with an external rotating force which is stronger than the predetermined reference force, the inside locking part 111 of the cap cover 100A escapes from the outside locking part 53 of the container 50, so that the cap cover 100A can be completely removed from the cap body 100B. In other words, the locking force to lock the inside locking part 111 of the cap cover 100A to the outside locking part 53 of the container 50 allows the container 50 to move upward in the vertical direction by the rotation of the cap cover 100A until the stop protrusion 54 of the container 50 is stopped by the cap body 100A. However, once the stop protrusion 54 of the container 50 is stopped by the cap body 100A, the locking force to lock the inside locking part 11 of the cap cover 100A to the outside locking part 53 of the container 50 cannot remove the stop protrusion 54 from the cap body 100B. Therefore, when the cap cover 100A in the above state is further rotated with the external rotating force which is stronger than the predetermined reference force, the inside locking part 111 of the cap cover 100A forcibly escapes from the outside locking part 53 of the container 50. Thus, the cap cover 100A can be completely removed from the cap body 100B.

As shown in FIGS. 5 and 6, the cap cover 100A is tightened to the open upper end 104 of the cap body 100B through screw-type engagement. The cap cover 100A has the inside locking part 111 on the inner circumferential surface thereof, as described above. The inside locking part 111 of the cap cover 100A is locked to the outside locking part 53 of the container 50. The inside locking part 111 and the outside locking part 53 constitute the locking means which locks the cap cover 100A to the container 50.

When the cap cover 100A is fully tightened to the open upper end 104 of the cap body 100B through the screw-type engagement, the cap cover 100A closes and seals the open upper end 104 of the cap body 100B.

The operation and effect of the cap device according to the third embodiment having the above-mentioned construction will be described herein below. After both a desired additive and compressed gas are injected into the space 51 of the container 50, the cap cover 100A is fully tightened to the open upper end 104 of the cap body 100B through the screw-type engagement, thus sealing the space 51 of the container 50 which contains both the additive and the compressed gas therein. In the third embodiment of the present invention, an example of the additive to be contained in the container 50 can be powdered green tea or medical drugs in the form of granules or powders, while an example of the compressed gas to be injected into the container 50 can be nitrogen gas or air. The cap device with both the additive and the compressed gas contained in the sealed space 51 of the container 50, is shown in FIG. 6.

To prepare a mixture by mixing the additive with a bottled material, the cap cover 100A is rotated to slightly open the cap device, as shown in FIG. 7a. In the above state, the flanged discharging port 52 of the container 50 is slightly spaced apart from the annular groove 222-2 (see FIG. 6) of the valve means 222 of the cap body 100B. Thus, the additive is discharged from the space 51 of the container 50 into the bottle 13 through the plurality of spaces defined between the radial ribs 222-1 (see FIG. 6) and added to the bottled material to prepare the desired mixture. While the additive is discharged from the space 51 of the container 50 into the bottle 13, the compressed gas in the space 51 promotes the discharge of the additive.

When the slightly opened cap cover 100A is further rotated to further open the cap device, as shown in FIG. 7b, the upper portion of the container 50 having the vent hole H moves upward so that the vent hole H is exposed above the upper end 104 of the cap body 100B. Thus, the vent hole H communicates with the atmosphere through the air paths 105 (see FIG. 8) which are provided on the outer circumferential surface of the upper end 104 of the cap body 100B. Therefore, atmospheric air is guided into the space 51 of the container 50 through the air paths 105 and the vent hole H to allow the additive to be almost completely discharged from the space 51 into the bottle 13, due to gravity.

When the cap cover 100A in the state of FIG. 7b is further rotated, the stop protrusion 54 that is provided on the outer circumferential surface of the additive container 50 at the intermediate position is stopped by the cap body 100A, thus stopping the upward movement of the additive container 50.

When the cap cover 100A in the above state is further rotated by an external rotating force which is stronger than the predetermined reference force, the inside locking part 111 of the cap cover 100A forcibly escapes from the outside locking part 53 of the container 50. Thus, the cap cover 100A is completely removed from the cap body 100B.

After the additive from the container 50 is mixed with the material contained in the bottle 13 to prepare the desired mixture according to the above-mentioned operation of the cap device, a user can drink or use the mixture by discharging the mixture from the bottle 13 through the open upper end of the container 50.

In the above state, the entire part of the cap device may be completely removed from the mouth 10 of the bottle 13, as desired, by loosening the cap body 100B from the mouth 10 of the bottle 13.

Meanwhile, when the user desires to drink or use the bottled material without mixing the additive of the cap device with the bottled material, the cap device in the state of FIG. 6 may be completely removed from the mouth 10 of the bottle 13 by loosening the cap body 100B from the mouth 10 of the bottle 13.

Fourth Embodiment

FIG. 9 is a sectional view of a cap device according to a fourth embodiment of the present invention, when the cap device is tightened to a mouth of a bottle. As shown in FIG. 9, the cap device according to the fourth embodiment of the present invention comprises a cap body 100B, an additive container 50 and a cap cover 100A. The cap body 100B is tightened to an externally threaded mouth 10 of a bottle 13, and defines a cylindrical space 103 inside the mouth 10 when the cap body 100B is tightened to the mouth 10. The additive container 50 is received in the cylindrical space 103 of the cap body 100B and has a space 51 therein to contain an additive in the space 51. The cap cover 100A is tightened to an open upper end of the cap body 100B to cover the open upper end of the cap body 100B.

In a detailed description, the cap body 100B has a double-walled structure at a lower portion thereof, in the same manner as that described for the third embodiment of the present invention. The double-walled structure of the cap body 100B includes an outer sidewall 101 and an inner sidewall 102. A valve means 222 is provided in the inner sidewall 102 of the cap body 100B at a lower end of the cylindrical space 103. Different from the valve means according to the third embodiment, the valve means 222 according to the fourth embodiment includes a plurality of vertical ribs 222-1 which extend downward from the cap body 100B in vertical directions at the lower end of the cylindrical space 103 of the cap body 100B. The valve means 222 further includes a circular valve part integrated with lower ends of the radial ribs 222-1. The circular valve part has a dome part 222-3 which is provided on a central area of the valve part.

The general shape of the additive container 50 according to the fourth embodiment remains the same as that described for the third embodiment. However, the additive container 50 according to the fourth embodiment does not have any stop projection on the circumferential outer surface thereof, and the lower end of the container 50 has no bottom wall, but linearly extends downward, thus forming a wide discharging opening 52, different from the third embodiment. The lower end surface of the discharging opening 52 of the container 50 is inclined upward and inward, thus providing an inclined surface. The discharging opening 52 of the container 50 is brought into close contact with the dome part 222-3 of the valve means 222 at the inclined surface thereof.

The operation and effect of the cap device according to the fourth embodiment having the above-mentioned construction will be described herein below.

The container 50 can contain therein a semisolid additive, such as ice cream, mustard sauce, thick soypaste mixed with red peppers or mayonnaise, while the bottle 13 can contain therein a desired material, such as a soda pop, a functional beverage, or soybean sauce. To mix the semisolid additive, for example, ice cream, with the bottled material, for example, soda pop, to prepare a mixture, the cap cover 100A is rotated relative to the cap body 100B. Thus, the container 50 moves upward in the vertical direction. Therefore, the ice cream is discharged from the space 51 of the container 50 into the bottle 13 through a plurality of wide spaces defined between the vertical ribs 222-1, thus being added to the soda pop in the bottle 13 to prepare the desired mixture. When a user shakes the bottle 13 in the above state, it is possible to more easily and quickly mix the ice cream with the soda pop.

Fifth Embodiment

FIG. 10 is a sectional view of a cap device according to a fifth embodiment of the present invention, when the cap device is tightened to a mouth of a bottle. As shown in FIG. 10, the cap device according to the fifth embodiment comprises a cap body 100B which is tightened to the mouth 10 of the bottle 13 through screw-type engagement. The cap body 100B defines a cylindrical space 103 therein. The cap device further includes an additive container 50 having a space 51 to contain an additive therein. The additive container 50 is received in the cylindrical space 103 of the cap body 100B. The cap device further includes a cylindrical control unit 100C which is assembled with the open upper end of the cap body 100B by an engaging ring 113 to rotate relative to the cap body 100B, with an internal thread provided on an inner circumferential surface of the control unit 100C to be tightened to an outer circumferential surface of the upper end of the additive container 50 through screw-type engagement. Thus, the control unit 100C controls a vertical movement of the additive container 50. The cap device further includes a cap cover 100A which is tightened to the upper end of the control unit 100C. In the cap device, an O-ring 112 is provided at a junction between the cap body 100B and the control unit 100C to accomplish a sealing effect at the junction. The engaging ring 113 extends upward from the upper end surface of the cap body 100B, and is inserted into an annular groove which is formed along the lower end of the control unit 100C. Thus, the cylindrical control unit 100C rotates relative to the cap body 100B. The cap device according to the fifth embodiment further includes a valve means 222 with the same construction as that of the fourth embodiment.

As shown in FIG. 10, the cylindrical control unit 100C is tightened to the outer circumferential surface of the upper end of the additive container 50 through the screw-type engagement. Thus, the container 50 moves upward and downward in a vertical direction by a rotation of the control unit 100C. In the same manner as that described for the fourth embodiment, the container 50 functions well for containing therein and discharging a semisolid additive, such as ice cream, mustard sauce, thick soypaste mixed with red peppers or mayonnaise, while the bottle 13 contains therein a desired material, such as a soda pop, a functional beverage, or soybean sauce.

Sixth Embodiment

FIG. 11 is a sectional view of a cap device according to a sixth embodiment of the present invention, when the cap device is tightened to a mouth of a bottle. As shown in FIG. 11, the cap device according to the sixth embodiment includes a cap body 100B which is tightened to the mouth 10 of the bottle 13 through screw-type engagement. The cap body 100B defines a cylindrical space 103 therein. The cap device further includes an additive container 50 having a space 51 to contain an additive therein. The additive container 50 is received in the cylindrical space 103 of the cap body 100B. The cap device further includes a cylindrical control unit 100C which is assembled with the open upper end of the cap body 100B by an engaging ring 113 to rotate relative to the cap body 100B. The engaging ring 113 extends upward from the upper end surface of the cap body 100B. The cap device further includes a cap cover 100A which is tightened to the upper end of the control unit 100C.

The general construction of the cap device according to the sixth embodiment remains the same as that described for the fifth embodiment. However, both the inner sidewall of the cap body 100B and the additive container 50 extend downward from a neck into an interior of the bottle 13 to a predetermined length. Furthermore, the cylindrical control unit 100C extends upward to a length which corresponds to the length of the downward extensions of both the cap body 100B and the additive container 50. The cap cover 100A is made of a plastic material, with a discharging hole 114 provided on the top wall of the cap cover 100A. The discharging hole 114 of the cap cover 100A may be provided with a cap (not shown).

Because both the cap body 100B and the additive container 50 extend downward from the neck into the interior of the bottle 13 as described above, a user easily mixes the additive with the bottled material to prepare a desired mixture.

In the present invention, the bottle 13 may be made of a soft plastic material which allows the user to discharge the mixture from the bottle 13 to the outside through the discharging hole 114 by compressing the bottle 13.

Seventh Embodiment

FIG. 12 is a sectional view of a cap device according to a seventh embodiment of the present invention, when the cap device is tightened to a mouth of a bottle. As shown in FIG. 12, the cap device according to the seventh embodiment includes a cap body 100B which is tightened to an open lower end 10 of the bottle 13 through screw-type engagement. The cap body 100B is opened at a lower end thereof, with a cylindrical space 103 defined in the cap body 100B and a valve means 222 provided in the cap body 100B at an upper end of the cylindrical space 103. The cap device further includes an additive container 50 which has a space 51 to contain an additive therein. The additive container 50 is received in the cylindrical space 103 of the cap body 10B, with a discharging opening 52 provided on an upper end of the additive container 50 to come in close contact with the valve means 222 of the cap body 100B. A lower end of the additive container 50 is opened and projected downward from the open lower end of the cap body 100B. The cap device further includes a cylindrical control unit 100C. The cylindrical control unit 100C is assembled with the open lower end of the cap body 100B by an engaging ring 113 to rotate relative to the cap body 100B, with an internal thread provided on an inner circumferential surface of the control unit 100C to be tightened to an outer circumferential surface of the lower end of the additive container 50 through screw-type engagement. The control unit 100C thus controls a vertical movement of the additive container 50.

The control unit 100C has a cup shape with a closed bottom, thus serving as a cap cover.

Even though the cap device according to the seventh embodiment is provided at the lower end of the bottle 13, different from the sixth embodiment in which the cap device is provided at the mouth of the bottle, the cap device according to the seventh embodiment provides the same operation and effect as those of the sixth embodiment.

Although embodiments of the present invention has been described for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims.

Claims

1. A cap device for a bottle having a mouth and neck, said cap device comprising:

a cap body formed to be tightened to said mouth of said bottle through screw-type engagement;

a funnel part integrally formed in the cap body to discharge an additive from the cap body into the bottle through a lower end thereof;

a cap cover provided on the cap body to cover an open upper end of the cap body while defining a space inside both the cap body and the cap cover; and

a valve means formed to open and close the lower end of the funnel part of the cap body according to a rotating action of the cap body relative to the externally threaded mouth of the bottle, wherein the valve means comprises a valve member having:

a conical valve part having a plurality of radial ribs extending outward from an external surface of the conical valve part in radial directions;

a ring integrated around the radial ribs for placement on an inner surface of said neck of the bottle;

said conical valve part formed to close the lower end of the funnel part when brought into closed contact with the lower end of the funnel part; and,

said conical valve part and ribs formed to open the lower end of the funnel part when the lower end of the funnel part is spaced apart from the lower end of the funnel part.

2. The cap device for bottles according to claim 1, wherein said conical valve part has

an upwardly extending plugging shank, said plugging shank having an externally threaded surface formed around the plugging shank; and,

said lower end of the funnel part having a threaded inner surface having the same pitch as the external thread of the plugging shank.

3. A cap device for a bottle having a mouth and neck, said cap device comprising:

a cap body formed to be tightened to said mouth of said bottle through screw-type engagement;

said cap body having an open upper end and a cylindrical space defined in the cap body; a

valve member disposed at a lower end of the cap body;

an additive container disposed in the cylindrical space of the cap body;

said additive container having a space to contain an additive therein, a discharging port provided on a lower end of the additive container positioned to be opened and closed by the valve member of the cap body;

said additive container having an open upper end; and,

a cap cover tightened to the open upper end of the cap body through screw-type engagement.

4. The cap device according to claim 3, wherein

the valve member comprises: a plurality of radial ribs extending inward from the cap body in radial directions at the lower end of the cylindrical space of the cap body; and, a circular valve part integrated with inside ends of the radial ribs, said circular valve part having both a dome part provided on a central area of the valve part and an annular groove part provided around the dome part.

5. The cap device according to claim 4 wherein said annular groove part is inclined upward and outward on an outside surface thereof, thus providing a first inclined surface; and,

the discharging port of the additive container is projected downward from a bottom wall of the container and is inclined upward and inward on a lower-end-surface thereof, thus providing a second inclined surface.

6. The cap device for bottles according to claim 3, wherein the additive container is rounded along an inside corner of a bottom wall leading to the discharging port.

7. The cap device for bottles according to claim 3, further comprising:

an outside locking part provided around an outer circumferential surface of the upper end of the additive container; and,

an inside locking part provided around an inner circumferential surface of the cap cover to engage with the outside locking part.

8. The cap device for bottles according to claim 3, further comprising:

a vent hole provided on an upper portion of a sidewall of the additive container; and

a plurality of air paths provided on an outer circumferential surface of the upper end of the cap body.

9. The cap device for bottles according to claim 3, further comprising:

a stop protrusion provided on an outer circumferential surface of the additive container at an intermediate position formed and arranged to stop the cap body at a predetermined distance during an upward movement of the additive container.

10. The cap device for bottles according to claim 3, wherein the valve member comprises:

a plurality of vertical ribs extending downward from the cap body in vertical directions at the lower end of the cylindrical space of the cap body;

a circular valve part integrated with lower ends of the vertical ribs, the circular valve part having a dome part on a central area thereof; and,

the discharging port of the additive container formed by linear extension of the lower end of the additive container downward.

11. The cap device as described in claim 10 wherein the discharging port is inclined upward and inward on a lower end surface thereof to provide an inclined surface so that the discharging port is brought into close contact with the dome part of the valve part at the inclined surface thereof when the discharging port is closed by the valve member.

12. A cap device for a bottle having a mouth, said cap device comprising:

a cap body tightened to said mouth of said bottle through screw-type engagement, the cap body having an open upper end and defining a cylindrical space in the cap body;

a valve member provided in the cap body at a lower end of the cylindrical space;

an additive container disposed in the cylindrical space of the cap body;

said additive container having a space therein to contain an additive therein;

a discharging opening disposed on a lower end of the additive container positioned to be closed and opened by the valve member of the cap body;

a control unit assembled with the open upper end of the cap body to rotate relative to the cap body;

said control unit having an internal threading provided on an inner circumferential surface of the control unit formed to be tightened to a threaded outer circumferential surface of the upper end of the additive container through screw-type engagement; and,

a cap cover tightened to an upper end of the control unit.

13. The cap device according to claim 12, further comprising:

an O-ring provided at a junction between the cap body and the control unit.

14. The cap device according to claim 12, wherein the valve member comprises:

a plurality of vertical ribs extending downward from the cap body in vertical directions at the lower end of the cylindrical space of the cap body; and,

a circular valve part integrated with lower ends of the vertical ribs, the circular valve part having a dome part on a central area thereof.

15. The cap device according to claim 14 wherein the lower end of the additive container having the discharging opening is inclined upward and inward on an end surface thereof to provide an inclined surface so that the lower end of the additive container is brought into close contact with the dome part of the valve part at the inclined surface thereof when the discharging opening is closed by the valve member.

16. The cap device according to claims 12, wherein the cap cover is provided with a discharging hole.

17. A cap device for a bottle having a mouth at a lower end of said bottle, said cap device comprising:

a cap body tightened to said mouth of said bottle through screw-type engagement, the cap body having an open upper end and defining a cylindrical space in the cap body;

the cap body being opened at a lower end thereof, with a cylindrical space defined in the cap body and valve member provided in the cap body at an upper end of the cylindrical space;

an additive container having a space to contain an additive therein, the additive container being received in the cylindrical space of the cap body;

a discharging opening provided on an upper end of the additive container to come in close contact with the valve member of the cap body;

a lower end of the additive container being opened and projected downward from the open lower end of the cap body; and

a control unit having a cup shape which is closed at a bottom thereof, the control unit being assembled with the open lower end of the cap body to rotate relative to the cap body, with an internal thread provided on an inner circumferential surface of the control unit to be tightened to an outer circumferential surface of the lower end of the additive container through screw-type engagement, so that the control unit controls a vertical movement of the additive container.

18. The cap device according to claim 17, further comprising:

an O-ring provided at a junction between the cap body and the control unit.

19. The cap device according to claim 18, wherein the valve member comprises:

a plurality of vertical ribs extending upward from the cap body in vertical directions at the upper end of the cylindrical space of the cap body; and,

a circular valve part integrated with upper ends of the vertical ribs, the circular valve part having a dome part on a central area thereof.

20. The cap device according to claim 19 wherein the upper end of the additive container having the discharging opening is inclined downward and inward on an end surface thereof to provide an inclined surface so that the upper end of the additive container is brought into close contact with the dome part of the valve part at the inclined surface thereof when the discharging opening is closed by the valve member.