KR101705030B1 - Automatic spuit type cap and automatic spuit type vessel comprising the same - Google Patents

Abstract

The present invention relates to an automatic eyedropper-type cap and an automatic eyedropper-type container comprising the same and, in accordance with one aspect of the present invention, An inner cap disposed to rotate integrally with the outer cap inside the outer cap, the inner cap having a helical first guide slot; A lifting cap disposed inside the inner cap and configured to rise along the first guide slot by rotation of the inner cap; A fixed cap disposed inside the lifting cap to engage with the lifting cap to guide the lifting and lowering movement of the lifting cap and to be detachably coupled to the container body; A pipe mounted to the fixed cap and having a flow path; And an elastic member provided to have a space communicating with the flow path of the pipe and having a volume of the space portion reduced when the lifting cap is moved down and a volume of the space portion increased when the lifting cap is lifted.

Description

[0001] The present invention relates to an automatic syringe-type cap and an automatic syringe-type container comprising the same,

The present invention relates to an automatic syringe-type cap and an automatic syringe-type container containing the same.

Cosmetics, usually composed of liquid contents, are stored in a container, and a syringe-type cap is used to withdraw the contents from the container.

However, the conventional eyedropper-type cap has a structure in which the opening of the cap for opening the container and the suction of the cap for pulling out the contents are separately made, and the usability is poor. In addition, the cap with a general eyed-type structure has a structure in which it is difficult to take out a predetermined amount each time it is used, because the amount of the contents to be sucked out depends on the degree of pressing by the user.

The present invention relates to an automatic syringe-type cap in which a suction is automatically performed to draw out contents in a container body based on an opening operation (for example, rotation of the cap) for opening the container body and an automatic syringe type container And the like.

According to an aspect of the present invention, there is provided an internal cap having an outer cap and an outer cap, the inner cap having a spiral first guide slot and disposed to rotate integrally with the outer cap, A lift cap disposed inside the lift cap to raise along the first guide slot by rotation of the inner cap, and engage with the lift cap to guide the lift cap up and down, The cap being fixed to the fixed cap, the pipe having a flow path and a space communicating with the flow path of the pipe, the volume of the space being reduced when the lifting cap is moved downward, An auto-syringe-type cap is provided.

According to still another aspect of the present invention, there is provided an apparatus for automatically opening and closing an opening of a container body having an opening portion and an automatic dropper cap for selectively opening and closing an opening portion of the container body, A syringe-type container is provided.

Wherein the automatic syringe-type cap is disposed within the inner cap, the inner cap having a helical first guide slot and disposed to rotate integrally with the outer cap and the outer cap within the outer cap, A lifting cap disposed to rise along the guide slot and a fixed cap disposed inside the lifting cap to engage with the lifting cap to guide the lifting and lowering movement of the lifting cap and to be detachably coupled to the opening of the container body, A volume of the space portion when the lifting cap is moved down and a volume of the space portion when the lifting cap is lifted up is increased, .

INDUSTRIAL APPLICABILITY As described above, the automatic syringe-type cap and the automatic syringe-type container including the same according to one embodiment of the present invention have the following effects.

The automatic drop cap has a structure in which an elastic member having a predetermined volume of space is connected to a pipe for sucking the contents in the container body. At this time, the automatic eyed-type cap is configured such that the volume of the space portion of the elastic member changes according to the rotation of the automatic eyed-type cap, and a force in the suction direction acts on the flow path in the pipe based on the volume change.

Therefore, the suction for withdrawing the contents in the container body based on the opening operation of the cap (for example, rotation of the cap) for opening the container body is automatically performed, and the ease of use can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a perspective view illustrating an automatic syringe-type cap in accordance with one embodiment of the present invention.
2 is an exploded perspective view of the automatic syringe-type cap shown in Fig.
FIGS. 3 and 4 are perspective views of the automatic eyed cap shown in FIG. 1, with some components removed.
5 to 7 are sectional views for explaining an operation state of an automatic dropper type container according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an automatic syringe type cap and an automatic syringe type container including the same according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In addition, the same or corresponding reference numerals are given to the same or corresponding reference numerals regardless of the reference numerals, and redundant description thereof will be omitted. For convenience of explanation, the size and shape of each constituent member shown in the drawings are exaggerated or reduced .

FIG. 1 is a perspective view showing an automatic eyed cap 100 according to an embodiment of the present invention, FIG. 2 is an exploded perspective view of the automatic eyed cap 100 shown in FIG. 1, and FIGS. 1 is a perspective view of a state in which some components are removed from an automatic drop cap 100 shown in FIG.

5 to 7 are sectional views for explaining an operation state of the automatic eyedrop container 1 according to an embodiment of the present invention.

5 shows a state in which the automatic eyedropper-type container 1 is closed with the automatic eyedropper-type cap 100. In FIG. 6 shows a state in which the contents M in the automatic dropper type container 1 are sucked into the automatic drop cap 100 according to the rotation of the automatic dropper cap 100. [ 7 shows a state in which the contents sucked into the automatic drop cap 100 flow out to the outside.

The automatic eyedropper type container 1 is provided to selectively open and close the container body 10 having the opening 11 and the opening 11 of the container body 10 and to open the container body 10 when the opening 11 is opened, And an automatic drop cap 100 for sucking the contents M therein. Here, opening of the container body 10 through the automatic drop cap 100 is achieved through rotation of the automatic drop cap 100. In addition, each component constituting the automatic dropper type container 1 may be formed of a resin, glass, or metal material generally used in cosmetic containers or the like.

Referring to FIG. 1, the automatic eyed cap 100 is provided to rotate about a center axis C. In this document, the vertical direction, the upper region and the lower region can be defined with reference to the center axis C direction (y axis direction).

2, the automatic drop cap 100 is disposed to rotate integrally with the outer cap 110 inside the outer cap 110 and the outer cap 110, and the spiral first guide slot 121 And an inner cap 120 having an inner surface.

The outer cap 110 forms the outer appearance of the automatic eyed cap 100 and may have a substantially hollow cylindrical shape. The user can separate the automatic eyed cap 110 from the container body 10 by manipulating (rotating) the outer cap 110. [ The outer cap 110 may be provided with a deco cap 180 for providing a beautiful outer appearance.

Further, the inner cap 120 is formed to have a smaller diameter than the outer cap, and may have a substantially hollow cylinder shape. The inner cap 120 is provided with a first guide slot 121 along the circumferential direction with respect to the center axis C and in particular the first guide slot 121 is formed spirally along the central axis C do.

The first guide slot 121 may be provided on the inner cap 120. For example, two first guide slots 121 may be formed along the circumferential direction of the inner cap 120 at predetermined intervals Respectively.

In addition, the inner cap 120 is disposed to engage with a portion of the outer cap 110 to rotate integrally with the outer cap 110. For example, the inner cap 120 is provided with a first engaging structure 122 having a concave-convex shape such as a gear or a latch on its outer circumferential surface. In addition, the outer cap 110 is provided with a second engagement structure for engaging with the first engagement structure 122 of the inner cap 120.

The outer cap 110 and the inner cap 120 may be integrally rotated only when the outer cap 110 is rotated in one direction (clockwise or counterclockwise).

The automatic drop cap 100 is disposed inside the inner cap 120 and includes a lifting cap 130 and a lifting cap 130 that are raised along the first guide slot 121 by rotation of the inner cap 120 And a fixed cap 140 for engaging with the lifting and lowering cap 130 to guide up and down movement of the lifting and lowering cap 130 and detachably coupled to the container body 10.

Referring to FIGS. 3 and 4, the lifting cap 130 may be provided with a lifting protrusion 132 inserted into the first guide slot 121. The lifting cap 130 and the inner cap 120 have a structure in which the lifting protrusion 132 is engaged with the first guide slot 121.

The first guide slot 121 includes a first region 121a located at the lower side along the spiral direction with respect to the center axis C and a second region 121b located at the upper side.

5, when the automatic eyed cap 100 is mounted on the opening 11 of the container body 10 (in a closed state), the lifting and lowering projection 132 of the lifting cap 130 is moved in the first guide slot Is located in the first region 121a of the first substrate 121.

3 and 6, when the automatic eyed cap 100 is separated from the opening 11 of the container body 10 by the rotation of the outer cap 110, the lifting protrusion 132 of the lifting cap 130 The lifting and lowering cap 130 moves upward with respect to the inner cap 110 as the first and second guiding slots 121 and 122 move along the first guide slot 121. The lifting and lowering protrusion 132 is positioned in the second area 121b of the first guide slot 121 when the lifting and lowering cap 130 is lifted relative to the inner cap 110. [

3 and 4, the lifting and lowering cap 130 is provided with a second guide slot 131 opened in the up and down direction, A projection 141 is provided. The second guide slot 131 is provided substantially parallel to the central axis C. The rotational force of the outer cap 110 can be sequentially transmitted to the fixed cap 140 by the engagement of the second guide slot 131 and the guide protrusion 141. [ As the outer cap 110 rotates, the inner cap 120 and the fixed cap 140 do not move up, but only the lifting cap 130 rises relative to the inner cap 120 and the fixed cap 140 .

When the lifting cap 130 is lifted up to the inner cap 120, the lifting protrusion 132 is positioned in the second region 121b of the first guide slot 121, Is positioned above the guide protrusion (141). The lifting protrusion 132 is positioned in the first area 121a of the first guide slot 121 and the lifting protrusion 132 is positioned on the guide protrusion 141. [ As shown in FIG.

In addition, the automatic eyed cap 100 is mounted on the fixed cap 140 and includes a pipe 150 having a flow path 151. The automatic eyed cap 100 includes an elastic member 160 provided to have a space portion 161 communicating with the flow path 151 of the pipe 150. The elastic member 160 may be formed of, for example, silicon.

The volume of the space portion 161 decreases when the lifting cap 130 is moved down and the volume of the space portion 161 increases when the lifting cap 130 is lifted. 6, when the volume of the space portion 161 of the elastic member 160 is increased, the suction force of the elastic member 160 toward the space portion 161 of the elastic member 160 is transmitted to the flow path of the pipe 150, Lt; / RTI >

The automatic eyed cap 100 may further include a cover cap 170 connected to the lifting cap 130 and adapted to contact the elastic member 160. The cover cap 170 may be provided on the upper portion of the lifting cap 130. The connection of the cover cap 170 with the lifting cap 130 may mean that the lifting cap 130 is lifted and the cover cap 170 is lifted up. The cover cap 170 and the lifting cap 130 may be connected to each other so as to be engaged with each other in some areas so that the cover cap 170 is not separated from the lifting cap 130. [

Here, the elastic member 160 is provided such that the space portion 161 is located in a space between the fixed cap 140 and the cover cap 170.

5, when the automatic eyed cap 100 is mounted on the opening 11 of the container body 10 (in a closed state), the lifting and lowering projection 132 of the lifting cap 130 is moved in the first guide slot Is located in the first region 121a of the first substrate 121. Also, the cover cap 170 engaged with the lifting cap 130 is positioned above the lifting cap 130 and comes close to the fixed cap 140. Accordingly, the space 161 of the elastic member 160 located between the fixed cap 140 and the cover cap 170 is maintained in a compressed state.

6, when the automatic eyed cap 100 is separated from the opening 11 of the container body 10 by the rotation of the outer cap 110, the lifting protrusion 132 of the lifting cap 130 is lifted 1 guide slot 121, the lifting cap 130 is lifted with respect to the inner cap 110.

As the lifting cap 130 is lifted, the compressed state of the space 161 of the elastic member 160 is released. When the volume of the space 161 of the elastic member 160 is increased, a suction force acts on the passage 151 of the pipe 150 toward the space 161 of the elastic member 160. Therefore, the content M in the container body 10 is sucked into the flow path 151 of the pipe 150.

Specifically, when the fixed cap 140 is separated from the container body 10 by the rotation of the outer cap 110, the lifting cap 130 is lifted and the elastic member 160 is lifted up So that the volume is increased. Further, as the volume of the space portion 161 increases, the expansion of the elastic member 160 can assist the rise of the lift cap and the rise of the cover cap 170. Also, when the cover cap 170 is lifted, at least a portion of the cover cap 170 may be exposed to the outside of the outer cap 110.

3 and 7, when the cover cap 170 is pressed toward the fixed cap 140, the volume of the space portion 161 is reduced in the elastic member 160, 1 guiding slot 121. In the present embodiment, When the volume of the space 161 of the elastic member 160 is reduced (compression of the elastic member), the contents accommodated in the flow path 151 of the pipe 150 are discharged to the outside of the pipe 150. Thus, the cover cap 170 functions as a button for discharging the contents sucked into the automatic drop cap 100 to the outside. The user can discharge the contents inside the pipe 150 to the outside of the pipe 150 by pressing the cover cap 170 exposed to the outside of the outer cap 110 toward the pipe 150 side.

On the other hand, the fixed cap 140 can be detachably and spirally coupled to the opening 11 of the container body 10. For this, a spiral portion 142 may be provided on the inner circumferential surface of the fixed cap 140. The outer peripheral surface of the opening 11 of the container main body 10 may be provided with a helical joining portion 12 which is helically engaged with the helical portion 142.

The foregoing description of the preferred embodiments of the present invention has been presented for purposes of illustration and various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention, And additions should be considered as falling within the scope of the following claims.

1: Automatic dropper type container
10:
100: Automatic drop cap
110: outer cap
120: inner cap
130: lifting cap
140: fixed cap
150: pipe
160: elastic member
170: Cover cap

Claims (14)

delete delete delete delete delete delete delete delete A container body having an opening provided with a helical engagement portion; And
And an automatic eyedropper cap for selectively opening and closing the opening of the container body and sucking the contents inside the container body when the opening is opened,
The auto-idle cap includes an outer cap;
An inner cap disposed to rotate integrally with the outer cap inside the outer cap, the inner cap having a helical first guide slot;
A lifting cap disposed inside the inner cap and configured to rise along the first guide slot by rotation of the inner cap;
A fixed cap disposed inside the lifting cap and having a spiral portion engaged with the lifting cap to guide up and down movement of the lifting cap and to be engaged with the spiral engagement portion so as to be detachably coupled to the opening of the container body;
A pipe attached to the fixed cap and extending into the container body, the pipe having a flow path;
An elastic member provided to have a space communicating with the flow path of the pipe and having a volume of the space portion when the lifting cap is moved down and a volume of the space portion when the lifting cap is lifted up; And
And a cover cap which is connected to be engaged with the lift cap in a part of the area and is arranged to be in contact with the elastic member,
The space portion of the elastic member is provided so as to be located in a space between the fixed cap and the cover cap,
When the fixed cap is separated from the container by the rotation of the outer cap, the lifting cap is raised, the elastic member is provided to increase the volume of the space, and as the volume of the space increases, A suction force is applied to the negative side, and the expansion of the elastic member is provided to assist the rise of the lift cap and the rise of the cover cap,
When the cover cap is pressed toward the fixed cap side, the elastic member is reduced in volume of the space portion, the contents accommodated in the flow path of the pipe are discharged to the outside of the pipe, and the lifting cap is lowered along the first guide slot. 10. The method of claim 9,
The lifting cap is provided with a lifting projection inserted into the first guide slot,
The lifting and lowering cap is provided with a second guide slot opened in the up-and-down direction,
And the fixed cap is provided with a guide projection to be inserted into the second guide slot. delete 11. The method of claim 10,
The first guide slot includes a first region located at a lower portion along a spiral direction with respect to a central axis and a second region located at an upper portion,
The lifting protrusion of the lifting and lowering cap is located in the first area of the first guide slot in a state that the automatic eyed cap is mounted on the opening of the container body,
The elevating protrusion is located at the bottom of the guide protrusion. 13. The method of claim 12,
When the automatic drop cap is separated from the opening of the container body by the rotation of the outer cap, the lifting and lowering cap rises with respect to the inner cap as the lifting and lowering projection of the lifting and lowering cap moves along the first guide slot, When completed, the lift projection is located in the second area of the first guide slot,
The elevating protrusion is located at the top of the guide protrusion. 13. The method of claim 12,
Wherein the elastic member is held in a compressed state with the space portion in a state in which the automatic drop cap is mounted on the opening of the container body.

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