WO2016171442A1

WO2016171442A1 - Automatic spuit type cap and automatic spuit type vessel including the same

Info

Publication number: WO2016171442A1
Application number: PCT/KR2016/004049
Authority: WO
Inventors: Ja Hong Ku
Original assignee: Daewoong Pharmaceutical Co., Ltd.
Priority date: 2015-04-24
Filing date: 2016-04-19
Publication date: 2016-10-27
Also published as: KR101644952B1

Abstract

The present invention relates to an automatic spuit type cap and an automatic spuit type vessel including the same, and the automatic spuit type cap according to an exemplary embodiment of the present invention includes: a massage unit which generates vibration; and a spuit unit which is connected with the massage unit and configured to selectively open and close a vessel main body, and to automatically suck contents in the vessel main body when the vessel main body is opened by a rotation of the automatic spuit type cap, in which the spuit unit is configured to discharge the sucked contents to the outside when the massage unit is moved toward the spuit unit.

Description

AUTOMATIC SPUIT TYPE CAP AND AUTOMATIC SPUIT TYPE VESSEL INCLUDING THE SAME

The present invention relates to an automatic spuit type cap and an automatic spuit type vessel including the same.

In general, cosmetics including liquid-phase contents are stored in vessels, and spuit type caps are used to extract the contents from the vessels.

However, in the case of the spuit type cap in the related art, an operation of opening the cap to open the vessel and a suction operation of the cap for extracting the contents are individually carried out, such that convenience for use deteriorates. In addition, in the case of a cap having a typical spuit structure, the amount of contents, which are sucked and extracted, varies depending on a degree to which a user pushes a pressing portion made of rubber, and a result, it is difficult to extract a constant amount of contents each time the user uses the cap.

An object of the present invention is to provide an automatic spuit type cap and an automatic spuit type vessel including the same, in which a suction operation for extracting contents in a vessel main body is automatically carried out based on an operation of opening a cap (e.g., a rotation of the cap) to open the vessel main body.

Another object of the present invention is to provide an automatic spuit type cap and an automatic spuit type vessel including the same, which are capable of providing a massage function using vibration.

To achieve the aforementioned objects, an exemplary embodiment of the present invention provides an automatic spuit type cap including: a massage unit which generates vibration; and a spuit unit which is connected with the massage unit and configured to selectively open and close a vessel main body, and to automatically suck contents in the vessel main body when the vessel main body is opened by a rotation of the automatic spuit type cap.

Here, the spuit unit may be configured to discharge the sucked contents to the outside when the massage unit is moved toward the spuit unit.

In addition, the massage unit and the spuit unit may be provided coaxially with each other, and connected to each other so as to be individually rotatable based on a central axis.

In addition, the massage unit may be configured to be rotated to selectively operate a vibrator.

In addition, the spuit unit may include: an outer cap; an inner cap which is disposed in the outer cap so as to be rotated integrally with the outer cap, and has a first spiral guide slot; a lifting cap which is disposed in the inner cap, configured to be moved along the first guide slot by a rotation of the inner cap, and connected with the massage unit; a fixing cap which is disposed in the lifting cap, engaged with the lifting cap so as to guide upward and downward movements of the lifting cap, and detachably coupled to the vessel main body; a pipe which is mounted on the fixing cap, and has a flow path; and an elastic member which is provided with a space portion that communicates with the flow path of the pipe, configured such that the space portion is positioned between the lifting cap and the massage unit, and configured such that a volume of the space portion is decreased when the massage unit is moved downward, and a volume of the space portion is increased when the lifting cap is moved upward.

In addition, when a volume of the space portion of the elastic member is increased, suction force may be applied to the flow path of the pipe toward the space portion.

In addition, when the massage unit is pressed toward the fixing cap, a volume of the space portion of the elastic member is decreased, and the lifting cap is moved downward along the first guide slot.

In addition, a lifting protrusion, which is inserted into the first guide slot, may be provided on the lifting cap.

In addition, a second guide slot, which is opened in an up and down direction, may be provided in the lifting cap, and a guide protrusion, which is inserted into the second guide slot, may be provided on the fixing cap.

In addition, a threaded portion may be provided on an inner circumferential surface of the fixing cap.

In addition, the massage unit may include: a cover cap which is connected with the spuit unit; a vibrator which is disposed in the cover cap; a massage member which is configured to surround the vibrator; a battery which is electrically connected with the vibrator so as to supply electric power to the vibrator; and a switch which selectively connects the battery and the vibrator.

In addition, the switch may be configured to be selectively turned on or off by a rotation of at least a partial region of the cover cap.

In addition, the cover cap may include: a lower cover which is connected with the spuit unit and to which the switch is fixed; an intermediate cover which is mounted to be rotatable relative to the lower cover; and an upper cover which is mounted on the intermediate cover so as to be separable so that the massage member is exposed.

In addition, an operating member, which extends toward the lower cover, may be provided on the intermediate cover, and the operating member may come into contact with the switch by a rotation of the intermediate cover so as to turn the switch on.

In addition, another exemplary embodiment of the present invention provides an automatic spuit type vessel including: a vessel main body which has an opening; and an automatic spuit type cap which is configured to selectively open and close the opening of the vessel main body, and includes a spuit unit that automatically sucks contents in the vessel main body when the vessel main body is opened by a rotation of the automatic spuit type cap, and a massage unit that is connected with the spuit unit and generates vibration.

In addition, the spuit unit may be configured to discharge the sucked contents to the outside when the massage unit is moved toward the spuit unit.

As described above, the automatic spuit type cap and the automatic spuit type vessel having the same according to the exemplary embodiment of the present invention have the following effects.

The automatic spuit type cap has a structure in which the elastic member having the space portion with a predetermined volume is connected to the pipe for sucking contents in the vessel main body. In this case, the automatic spuit type cap is configured such that a volume of the space portion of the elastic member is changed by a rotation of the automatic spuit type cap, and force is applied to the flow path of the pipe in a suction direction in accordance with the change in volume.

Therefore, a suction operation for extracting contents in the vessel main body is automatically carried out in accordance with an operation of opening the cap (e.g., a rotation of the cap) to open the vessel main body, thereby improving convenience for use.

In addition, it is possible to provide a massage function using vibration.

FIG. 1 is a perspective view illustrating an automatic spuit type cap according to an exemplary embodiment of the present invention.

FIG. 2 is an exploded perspective view of the automatic spuit type cap illustrated in FIG. 1.

FIG. 3 is an exploded cross-sectional view of the automatic spuit type cap illustrated in FIG. 2.

FIGS. 4 and 5 are perspective views illustrating states in which some constituent elements are removed from the automatic spuit type cap illustrated in FIG. 1.

FIGS. 6 to 8 are cross-sectional views for explaining one operational state of an automatic spuit type vessel according to the exemplary embodiment of the present invention.

FIGS. 9 and 10 are cross-sectional views for explaining one operational state of the automatic spuit type cap according to the exemplary embodiment of the present invention.

Hereinafter, an automatic spuit type cap and an automatic spuit type vessel including the same according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In addition, the same or corresponding constituent elements will be designated by the same or similar reference numerals regardless of reference numerals, and a duplicated description thereof will be omitted. For convenience of description, sizes and shapes of the illustrated constituent elements may be exaggerated or reduced.

FIG. 1 is a perspective view illustrating an automatic spuit type cap 100 according to an exemplary embodiment of the present invention, FIG. 2 is an exploded perspective view of the automatic spuit type cap 100 illustrated in FIG. 1, and FIG. 3 is an exploded cross-sectional view of the automatic spuit type cap 100 illustrated in FIG. 2.

In addition, FIGS. 4 and 5 are perspective views illustrating states in which some constituent elements are removed from the automatic spuit type cap 100 illustrated in FIG. 1.

Here, FIG. 6 illustrates a state in which an automatic spuit type vessel 1 is closed by the automatic spuit type cap 100. In addition, FIG. 7 illustrates a state in which contents M in the automatic spuit type vessel 1 are sucked into the automatic spuit type cap 100 by a rotation of the automatic spuit type cap 100. In addition, FIG. 8 illustrates a state in which the contents, which have been sucked into the automatic spuit type cap 100, are being discharged to the outside.

FIGS. 9 and 10 are cross-sectional views for explaining one operational state of the automatic spuit type cap 100 according to the exemplary embodiment of the present invention, and particularly, cross-sectional views for explaining a massage function.

The automatic spuit type vessel 1 includes a vessel main body 10 having an opening 11, and the automatic spuit type cap 100. The respective constituent elements, which constitute the automatic spuit type vessel 1, may be made of resin, glass, or a metallic material which is typically used for a cosmetic vessel or the like.

The automatic spuit type cap 100 includes a spuit unit 101 which is configured to selectively open and close the opening 11 of the vessel main body 10 and automatically sucks the contents M in the vessel main body 10 when the vessel main body 11 is opened by a rotation of the automatic spuit type cap, and a massage unit 200 which is connected with the spuit unit 101 and generates vibration.

In addition, the spuit unit 101 is configured to discharge the sucked contents to the outside when the massage unit 200 is moved toward the spuit unit 101. In addition, the vessel main body 10 is opened by the automatic spuit type cap 100 by rotating the automatic spuit type cap 100.

Referring to FIG. 1, the automatic spuit type cap 100 is configured to be rotated about a central axis C. In the present specification, up and down directions, an upper region, and a lower region may be defined based on a direction of the central axis C (y-axis direction).

Hereinafter, the spuit unit 101, which constitutes the automatic spuit type cap 100, will be specifically described with reference to the accompanying drawings.

Referring to FIGS. 2 to 6, the spuit unit 101 includes an outer cap 110, and an inner cap 120 which is disposed in the outer cap 110 so as to be rotated integrally with the outer cap 110 and has a first spiral guide slot 121.

The outer cap 110 defines an external appearance of the automatic spuit type cap 100, and may have an approximately hollow cylindrical shape. A user may separate the automatic spuit type cap 110 from the vessel main body 10 by manipulating (rotating) the outer cap 110. In addition, a deco cap for presenting an aesthetically attractive external appearance may be mounted on the outer cap 110.

In addition, the inner cap 120 is formed to have a smaller diameter than the outer cap 110, and may have an approximately hollow cylindrical shape. In addition, the first guide slot 121 is provided in the inner cap 120 in a circumferential direction based on the central axis C, and particularly, the first guide slot 121 is provided in a spiral manner in the central axis direction C.

Here, a plurality of first guide slots 121 may be provided in the inner cap 120, and for example, two first guide slots 121 may be provided in the inner cap 120 in the circumferential direction at a predetermined interval.

In addition, the inner cap 120 is disposed to be engaged with a partial region of the outer cap 110 so as to be rotated integrally with the outer cap 110. For example, a first engagement structure 122, which has concave-convex portions such as a gear or a latch, is provided on an outer circumferential surface of the inner cap 120. In addition, a second engagement structure, which is engaged with the first engagement structure 122 of the inner cap 120, is provided on the outer cap 110.

In addition, the outer cap 110 and the inner cap 120 may be configured to be integrally rotated only when the outer cap 110 is rotated in one direction (clockwise or counterclockwise).

In addition, the spuit unit 101 includes a lifting cap 130 which is disposed in the inner cap 120 and configured to move along the first guide slot 121 by the rotation of the inner cap 120, and a fixing cap 140 which is disposed in the lifting cap 130, engaged with the lifting cap 130 so as to guide the upward and downward movement of the lifting cap 130, and detachably coupled to the vessel main body 10. The lifting cap 130 is configured to be moved upward and downward along the first guide slot 121 by the rotation of the inner cap 120. Specifically, the lifting cap 130 is configured to be moved upward and downward along the first guide slot 121 as the inner cap 120 is rotated in a predetermined direction.

Referring to FIGS. 2, 4 and 5, a lifting protrusion 132, which is inserted into the first guide slot 121, may be provided on the lifting cap 130. The lifting cap 130 and the inner cap 120 are constructed to be engaged with each other as the lifting protrusion 132 is disposed in the first guide slot 121.

Here, the first guide slot 121 includes a first region 121a positioned at a lower side and a second region 121b positioned at an upper side, in the spiral direction based on the central axis C.

Referring to FIG. 6, in a state in which the automatic spuit type cap 100 is mounted at the opening 11 of the vessel main body 10 (a closed state), the lifting protrusion 132 of the lifting cap 130 is positioned in the first region 121a of the first guide slot 121.

Referring to FIGS. 4 and 7, when the automatic spuit type cap 100 is separated from the opening 11 of the vessel main body 10 by the rotation of the outer cap 110, the lifting protrusion 132 of the lifting cap 130 moves along the first guide slot 121, such that the lifting cap 130 is moved upward relative to the inner cap 110. When the lifting cap 130 is moved upward relative to the inner cap 110, the lifting protrusion 132 is positioned in the second region 121b of the first guide slot 121.

In addition, referring to FIGS. 4 and 5, a second guide slot 131, which is opened in an up and down direction, is provided in the lifting cap 130. Here, a plurality of second guide slots 131 may be provided in the lifting cap 130, and for example, two second guide slots 131 may be provided in the lifting cap 130 in the circumferential direction at a predetermined interval in parallel with the central axis C.

In addition, a guide protrusion 141, which is inserted into the second guide slot 131, provided on the fixing cap 140. The second guide slot 131 is provided to be substantially parallel to the central axis C. With the engagement between the second guide slot 131 and the guide protrusion 141, rotational force of the outer cap 110 may be sequentially transmitted to the fixing cap 140. Meanwhile, when the outer cap 110 is rotated, the inner cap 120 and the fixing cap 140 are not moved upward, but only the lifting cap 130 is moved upward relative to the inner cap 120 and the fixing cap 140.

In addition, when the lifting cap 130 is completely moved upward relative to the inner cap 120, the lifting protrusion 132 is positioned in the second region 121b of the first guide slot 121, and the lifting protrusion 132 is positioned above the guide protrusion 141. On the contrary, when the lifting cap 130 is completely moved downward, the lifting protrusion 132 is positioned in the first region 121a of the first guide slot 121, and the lifting protrusion 132 is positioned below the guide protrusion 141.

In addition, the spuit unit 101 includes a pipe 150 which is mounted on the fixing cap 140 and has a flow path 151. In addition, the spuit unit 101 includes an elastic member 160 which has a space portion 161 that communicates with the flow path 151 of the pipe 150. The elastic member 160 may be made of, for example, silicone.

The elastic member 160 is configured such that a volume of the space portion 161 is decreased when the massage unit 200 is moved downward, and a volume of the space portion 161 is increased when the lifting cap 130 is moved upward. With the aforementioned structure, referring to FIG. 7, when a volume of the space portion 161 of the elastic member 160 is increased, suction force is applied to the flow path of the pipe 150 toward the space portion 161 of the elastic member 160 in a direction indicated by the arrow.

In addition, the automatic spuit cap 100 includes the massage unit 200 which is connected with the lifting cap 130 and is configured to be in contact with the elastic member 160.

Specifically, the massage unit 200 may include a cover cap 210 which is connected with the spuit unit 101, a vibrator 250 which is disposed in the cover cap 210, and a massage member 260 which is configured to surround the vibrator 250. Here, the vibrator 250 may be an ultrasonic vibrator. In addition, the massage member 260 comes into contact with a user's skin and serves to transmit vibration to the user's skin, and an outer circumferential surface of the massage member 260 may be formed to have a curved surface.

In addition, the massage unit 200 may include a battery 270 which is electrically connected with the vibrator 250 so as to supply electric power to the vibrator 250, and a switch 280 which selectively connects the battery 270 and the vibrator 250. Meanwhile,

non-described reference numerals

271 and 272 indicate battery connecting portions for electrical connection.

The cover cap 210 may include a lower cover 240 which is connected with the spuit unit 101 and to which the switch 280 is fixed, an intermediate cover 230 which is mounted to be rotatable relative to the lower cover 240, and an upper cover 220 which is mounted on the intermediate cover 230 so as to be separable so that the massage member 260 is exposed to the outside.

The cover cap 210 may be configured to be positioned above the lifting cap 130 of the spuit unit 101. The description that the cover cap 210 is connected with the spuit unit 101 means that the cover cap 210 is connected with the lifting cap 130. In addition, the description that the cover cap 210 is connected with the lifting cap 130 means that the cover cap 210 is connected with the lifting cap 130 so that the cover cap 210 may be moved upward as the lifting cap 130 is moved upward. In addition, the cover cap 210 and the lifting cap 130 may be connected to be engaged with each other in a partial region by means of a catching projection or the like in order to prevent the cover cap 210 from being withdrawn (separated) from the lifting cap 130. In addition, the cover cap 210 may be provided in the outer cap 110 so as to be movable upward and downward. In addition, the cover cap 210 may be configured to be movable upward and downward together with the lifting cap 130. In addition, the cover cap 210 connected with the lifting cap 130 means the lower cover 240.

Here, the elastic member 160 is configured such that the space portion 161 is positioned in a space between the fixing cap 140 and the cover cap 210. The elastic member 160 is configured such that the space portion 161 is positioned between the fixing cap 140 and the lower cover 240. In addition, the elastic member 160 may be configured to be in contact with the cover cap 210. Specifically, the elastic member 160 may be configured to be in contact with the lower cover 240.

Referring to FIGS. 4 and 6, in a state in which the automatic spuit type cap 100 is mounted at the opening 11 of the vessel main body 10 (a closed state), the lifting protrusion 132 of the lifting cap 130 is positioned in the first region 121a of the first guide slot 121. In addition, the cover cap 210, which is engaged with the lifting cap 130, is positioned above the lifting cap 130 and becomes close to the fixing cap 140. Therefore, the space portion 161 of the elastic member 160, which is positioned between the fixing cap 140 and the cover cap 210, is kept relatively compressed.

Referring to FIG 7, when the automatic spuit type cap 100 is separated from the opening 11 of the vessel main body 10 by the rotation of the outer cap 110, the lifting protrusion 132 of the lifting cap 130 moves along the first guide slot 121, such that the lifting cap 130 is moved upward relative to the inner cap 110.

Here, the compressed state of the space portion 161 of the elastic member 160 is relatively released by the upward movement of the lifting cap 130. In addition, as a volume of the space portion 161 of the elastic member 160 is increased, suction force is applied to the flow path 151 of the pipe 150 toward the space portion 161 of the elastic member 160. Therefore, the contents M in the vessel main body 10 are sucked into the flow path 151 of the pipe 150.

Specifically, when the fixing cap 140 is separated from the vessel main body 10 by the rotation of the outer cap 110, the lifting cap 130 is moved upward, and a volume of the space portion 161 of the elastic member 160 is increased. In addition, as a volume of the space portion 161 is increased, the expansion of the elastic member 160 may assist the upward movement of the lifting cap 130 and the upward movement of the cover cap 210. In addition, the cover cap 210 may be configured such that a partial region of the lower cover 240 is exposed to the outside of the outer cap 110 when the cover cap 210 is moved upward.

Meanwhile, referring to FIGS. 4 and 8, when the massage unit 200 is pressed toward the fixing cap 140, a volume of the space portion 161 of the elastic member 160 is decreased, and the lifting cap 130 is moved downward along the first guide slot 210. When the user presses the cover cap 210 toward the fixing cap 140, a volume of the space portion 161 of the elastic member 160 is decreased, and the lifting cap 130 is moved downward along the first guide slot 121. In addition, when a volume of the space portion 161 of the elastic member 160 is decreased (the elastic member is compressed), the contents accommodated in the flow path 151 of the pipe 150 are discharged to the outside of the pipe 150. As described above, the cover cap 210 functions as a button for discharging the contents, which have been sucked into the automatic spuit type cap 100, to the outside. The user may discharge the contents in the pipe 150 to the outside of the pipe 150 by pressing the cover cap 210, which defines an external appearance of the massage unit 200, toward the pipe 150.

Meanwhile, the massage unit 200 and the spuit unit 101 are provided coaxially with each other (e.g., on the central axis C), and may be connected to each other so as to be individually rotatable based on the central axis C. With the aforementioned structure, the user may individually use a massage function and a spuit function, thereby improving convenience for use.

In addition, the massage unit 200 may be configured such that the vibrator 250 is selectively operated by a rotation of the massage unit 200.

Referring to FIGS. 3, 9 and 10, the switch 260 may be configured to be selectively turned on or off by a rotation of at least a partial region (e.g., the intermediate cover 230) of the cover cap 210. Referring to FIG. 3, an operating member 235, which extends toward the lower cover 240, may be provided on the intermediate cover 230. Referring to FIG. 10, the operating member 235 comes into contact with the switch 280 by a rotation of the intermediate cover 230, thereby turning the switch 280 on.

FIG. 10A illustrates a state in which the switch is turned off, and FIG. 10B illustrates a state in which the switch is turned on.

With the aforementioned structure, the massage member 260 is exposed to the outside when the user separates the upper cover 220 from the intermediate cover 230. In this case, when the intermediate cover 230 is rotated to supply electric power to the vibrator 250, the user may use a vibration function of the automatic spuit type cap 100. Particularly, in a case in which the automatic spuit type vessel is a cosmetic vessel which accommodates cosmetics including liquid-phase contents, cosmetics may be sucked and discharged by the automatic spuit cap 100, and the massage unit 200 is operated after the user applies cosmetics, thereby providing vibration to a region on which the cosmetics are applied.

Meanwhile, the fixing cap 140 may be separably thread-coupled to the opening 11 of the vessel main body 10. For example, a threaded portion 142 may be provided on an inner circumferential surface of the fixing cap 140. In addition, a thread-coupling portion 12, which is thread-coupled to the threaded portion 142, may be provided on an outer circumferential surface of the opening 11 of the vessel main body 10.

It should be understood that the aforementioned exemplary embodiments of the present invention are described for illustration, and may be variously modified, changed, and added by those skilled in the art without departing from the spirit and scope of the present invention, and the modification, change, and addition belong to the appended claims.

A suction operation for extracting contents in the vessel main body is automatically carried out in accordance with an operation of opening the cap (e.g., a rotation of the cap) to open the vessel main body, thereby improving convenience for use.

Claims

An automatic spuit type cap comprising:

a massage unit which generates vibration; and

a spuit unit which is connected with the massage unit and configured to selectively open and close a vessel main body, and to automatically suck contents in the vessel main body when the vessel main body is opened by a rotation of the automatic spuit type cap,

wherein the spuit unit is configured to discharge the sucked contents to the outside when the massage unit is moved toward the spuit unit.
The automatic spuit type cap of claim 1, wherein the massage unit and the spuit unit are provided coaxially with each other, and connected to each other so as to be individually rotatable based on a central axis.
The automatic spuit type cap of claim 2, wherein the massage unit is configured to be rotated to selectively operate a vibrator.
The automatic spuit type cap of claim 1, wherein the spuit unit includes:

an outer cap;

an inner cap which is disposed in the outer cap so as to be rotated integrally with the outer cap, and has a first spiral guide slot;

a lifting cap which is disposed in the inner cap, configured to be moved along the first guide slot by a rotation of the inner cap, and connected with the massage unit;

a fixing cap which is disposed in the lifting cap, engaged with the lifting cap so as to guide upward and downward movements of the lifting cap, and detachably coupled to the vessel main body;

a pipe which is mounted on the fixing cap, and has a flow path; and

an elastic member which is provided with a space portion that communicates with the flow path of the pipe, configured such that the space portion is positioned between the lifting cap and the massage unit, and configured such that a volume of the space portion is decreased when the massage unit is moved downward, and a volume of the space portion is increased when the lifting cap is moved upward.
The automatic spuit type cap of claim 4, wherein when a volume of the space portion of the elastic member is increased, suction force is applied to the flow path of the pipe toward the space portion.
The automatic spuit type cap of claim 4, wherein when the massage unit is pressed toward the fixing cap, a volume of the space portion of the elastic member is decreased, and the lifting cap is moved downward along the first guide slot.
The automatic spuit type cap of claim 4, wherein a lifting protrusion, which is inserted into the first guide slot, is provided on the lifting cap.
The automatic spuit type cap of claim 7, wherein a second guide slot, which is opened in an up and down direction, is provided in the lifting cap, and

a guide protrusion, which is inserted into the second guide slot, is provided on the fixing cap.
The automatic spuit type cap of claim 4, wherein a threaded portion is provided on an inner circumferential surface of the fixing cap.
The automatic spuit type cap of claim 1, wherein the massage unit includes:

a cover cap which is connected with the spuit unit;

a vibrator which is disposed in the cover cap;

a massage member which is configured to surround the vibrator;

a battery which is electrically connected with the vibrator so as to supply electric power to the vibrator; and

a switch which selectively connects the battery and the vibrator.
The automatic spuit type cap of claim 10, wherein the switch is configured to be selectively turned on or off by a rotation of at least a partial region of the cover cap.
The automatic spuit type cap of claim 10, wherein the cover cap includes:

a lower cover which is connected with the spuit unit and to which the switch is fixed;

an intermediate cover which is mounted to be rotatable relative to the lower cover; and

an upper cover which is mounted on the intermediate cover so as to be separable so that the massage member is exposed.
The automatic spuit type cap of claim 12, wherein an operating member, which extends toward the lower cover, is provided on the intermediate cover, and the operating member comes into contact with the switch by a rotation of the intermediate cover so as to turn the switch on.
An automatic spuit type vessel comprising:

a vessel main body which has an opening; and

an automatic spuit type cap which is configured to selectively open and close the opening of the vessel main body, and includes a spuit unit that automatically sucks contents in the vessel main body when the vessel main body is opened by a rotation of the automatic spuit type cap, and a massage unit that is connected with the spuit unit and generates vibration,

wherein the spuit unit is configured to discharge the sucked contents to the outside when the massage unit is moved toward the spuit unit.