KR20240007536A - Container - Google Patents

Abstract

According to an embodiment of the present invention, a container for contents is provided. The content container includes a container portion for accommodating the content; a discharge unit coupled to the upper side of the container unit and provided with a nozzle unit for discharging the contents; and an elevating part coupled to the outside of the ejection part to surround at least a portion of the ejection part, and adjusting exposure of the nozzle part while moving up and down between a first position and a second position according to a rotation operation of the user, wherein the elevating part is raised and lowered. At this time, the discharge part may rotate synchronously with the lifting part.

Description

Content container {CONTAINER}

The present invention relates to a container for contents.

Pump containers are widely used because they have the advantage of being able to easily discharge the contents through pressurization. In general, the pump container is configured so that when the pump is operated by pressing the button on which the nozzle is formed, the contents contained in the container are transferred to the upper side and discharged to the outside in a fixed amount through the nozzle. In the case of such pump containers, in order to prevent contamination of the nozzle and unintentional pressurization of the pump, a stopper portion that shields the button portion is generally provided.

However, the conventional method of attaching and detaching the stopper involves the inconvenience of having to attach and detach the stopper every time the pump container is used, and because the stopper is completely separated from the pump container, there is a risk of losing the stopper. In addition, the cap may be unintentionally separated during the carrying process of the pump container, and the problem of the contents being randomly discharged to the outside due to contamination of the nozzle and pressurization of the button arises again.

The purpose of the present invention is to provide a container for contents to solve the above problems.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below.

According to an embodiment of the present invention, a container for contents is provided. The content container includes a container portion for accommodating the content; a discharge unit coupled to the upper side of the container unit and provided with a nozzle unit for discharging the contents; and an elevating part coupled to the outside of the ejection part to surround at least a portion of the ejection part, and adjusting exposure of the nozzle part while moving up and down between a first position and a second position according to a rotation operation of the user, wherein the elevating part is raised and lowered. At this time, the discharge unit may rotate synchronously with the elevating unit.

In addition, an accommodating groove for accommodating the nozzle unit at the second position is provided at the upper end of the elevating part, and when the elevating part is lifted/lowered, the accommodating groove and the nozzle part rotate together due to synchronous rotation of the elevating part and the discharge part. Mutual alignment can be maintained.

In addition, it is coupled to the inside of the elevating part and further includes a guide part that guides the elevating part of the elevating part, and at least one elevating guide protrusion is provided on the outside of the guide part, and the elevating guide protrusion is inserted into the elevating part. At least one inclined groove is provided, and when a rotational operation is applied to the lifting unit, the lifting guide protrusion relatively rotates along the inclined groove, and the lifting unit can move up and down.

Additionally, the guide unit may include: a first guide unit provided with the lifting guide protrusion; And a second guide part that rotates relative to the first guide part inside the first guide part, is coupled to rotate synchronously with the lifting part and the discharge part, and transmits the rotational force of the lifting part to the discharging part. .

In addition, at least one fitting groove is formed extending a predetermined length along the inner peripheral surface of the first guide part, and at least one fitting protrusion is formed on the outside of the second guide part to be inserted into the fitting groove, and the fitting protrusion is formed in the fitting groove. As it moves along the groove, the first guide part and the second guide part may rotate relative to each other.

In addition, at least one rotation guide protrusion is provided on the outside of the second guide part, and at least one vertical groove into which the rotation guide protrusion is inserted is provided on the inside of the elevating part, and when the elevating part rotates, the rotation guide protrusion The second guide part may be rotated while moving along the vertical groove.

In addition, at least one coupling groove is provided on the inside of the second guide part, and at least one coupling protrusion inserted into the coupling groove is provided on the outside of the discharge part, and the second guide part is rotated by rotation of the elevating part. When this happens, the discharge unit can be rotated by combining the coupling groove and the coupling protrusion.

Additionally, the lifting unit may include a first lifting unit provided with the inclined groove; And it may include a second lifting part that is coupled to the outside of the first lifting part to rotate synchronously with the first lifting part and receives the rotation operation.

In addition, the container portion includes a receiving portion that accommodates the contents; and a pump assembly provided between the receiving part and the discharging part, which compresses and decompresses when the discharging part is pressurized and moves the contents toward the discharging part.

In addition, at least one limiting protrusion is provided on the inside of the discharge part, and a first moving groove is formed in an upper area of the guide part into which the limiting protrusion is rotatably inserted along the circumferential direction, and the first moving groove of the first moving groove When a second moving groove is cut in a vertical direction from one area and the limiting protrusion is aligned with the upper side of the second moving groove at the first position, pressing of the discharge unit may be permitted.

According to the present invention, by rotating the lifting part, the exposure of the nozzle part can be adjusted according to the user's intention, and through this, contamination of the nozzle part can be minimized.

Additionally, according to the present invention, the nozzle is shielded or exposed while the lifting unit rotates and goes up and down, thereby providing a unique feeling of operation.

In addition, according to the present invention, it is possible to control whether or not to allow pressurization of the discharge part by rotating the lifting part. Pressurizing the discharge part is possible only when the lifting part is completely lowered, and pressurizing the discharge part can be limited when the lifting part rises.

Additionally, according to the present invention, since the lifting part and the discharge part rotate synchronously, the position of the nozzle part can always be aligned at a predetermined position with respect to the lifting part despite the rotation of the lifting part.

In order to more fully understand the drawings cited in the detailed description of the present invention, a brief description of each drawing is provided.
1 is a perspective view of a container with contents according to an embodiment of the present invention.
Figure 2 is an exploded perspective view of a container with contents according to an embodiment of the present invention.
Figure 3 is a cross-sectional view of a container with contents according to an embodiment of the present invention.
Figure 4 is a perspective view of a discharge unit according to an embodiment of the present invention.
Figure 5 is an exploded perspective view of an elevating part according to an embodiment of the present invention.
Figure 6 is an exploded perspective view of the guide portion according to an embodiment of the present invention.
Figure 7 is a diagram for explaining the operation of the content container according to an embodiment of the present invention.
Figure 8 is a diagram for explaining the operation of the first guide unit and the lifting unit according to an embodiment of the present invention.
Figure 9 is a diagram for explaining the operation of the lifting unit and the second guide unit according to an embodiment of the present invention.
Figure 10 is a diagram for explaining the operation of the second guide unit and the discharge unit according to an embodiment of the present invention.

Hereinafter, exemplary embodiments according to the present invention will be described in detail with reference to the contents depicted in the attached drawings. In addition, a method of configuring and using a device according to an embodiment of the present invention will be described in detail with reference to the contents described in the attached drawings. The same reference numbers or symbols shown in each drawing indicate parts or components that perform substantially the same function. For convenience, the up, down, left, and right directions described below are based on the drawings, and the scope of the present invention is not necessarily limited to those directions.

Terms containing ordinal numbers, such as first, second, etc., may be used to describe various components, but the components are not limited by the terms. Terms are used only to distinguish one component from another. For example, a first component may be referred to as a second component, and similarly, the second component may be referred to as a first component without departing from the scope of the present invention. The term and/or includes a combination of a plurality of related items or any one item among a plurality of related items.

The terms used herein are used to describe embodiments and are not intended to limit and/or limit the invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, terms such as include or have are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are intended to indicate the presence of one or more other features, numbers, or steps. , it should be understood that this does not exclude in advance the possibility of the presence or addition of operations, components, parts, or combinations thereof.

Throughout the specification, when a part is said to be connected to another part, this includes not only cases where it is directly connected, but also cases where it is indirectly connected with another component in between. Additionally, when it is said that a part includes a certain component, this does not mean that other components are excluded, but that it can further include other components, unless specifically stated to the contrary.

Figure 1 is a perspective view of a content container according to an embodiment of the present invention, Figure 2 is an exploded perspective view of a content container according to an embodiment of the present invention, Figure 3 is a cross-sectional view of a content container according to an embodiment of the present invention, Figure 4 is an exploded perspective view of the guide portion according to an embodiment of the present invention, Figure 5 is an exploded perspective view of the elevating portion according to an embodiment of the present invention, and Figure 6 is a perspective view of the discharge portion according to an embodiment of the present invention. Specifically, in FIGS. 1 and 3, (a) shows the content container in a first position, and (b) shows the content container in the second position.

Referring to FIGS. 1 to 6 , the content container 1000 may include a container portion 100, a discharge portion 200, an elevation portion 300, and/or a guide portion 400.

The container unit 100 can accommodate contents and move the contents toward the discharge unit 200 by applying pressure. In an embodiment, container portion 100 may include a receiving portion 110 and a pump assembly 120.

The receiving portion 110 can accommodate contents. Here, the contents may be liquid, gel, or powder cosmetics. For example, the contents include lotion, milk lotion, moisture lotion, nutritional lotion, skin lotion, skin softener, skin toner, astringent, massage cream, nutritional cream, moisture cream, whitening essence, tone-up cream, sunscreen, sunscreen, sunscreen. It may include milk, BB cream, base, foundation, CC cream, concealer, blusher, shading, eye shadow, eyebrow, eye cream, primer, etc. However, it is not limited to this, and other formulations or types of cosmetics, medical contents, etc. may be applied.

In an embodiment, the receiving portion 110 may be freely selected from various known types of containers, such as bottles, jars, tubes, and pouch containers, in which a receiving space is formed on the inside. .

The pump assembly 120 is provided on the upper side of the receiving part 110, especially between the receiving part 110 and the discharge part 200, and is compressed and decompressed (when the discharge part 200 is pressurized) and releases the contents into the discharge part. It can be moved to the (200) side.

For example, the pump assembly 120 includes a cylinder whose upper and lower portions are open and a hollow interior is formed; A seal cap that is in close contact with the cylinder and moves up and down inside the cylinder; a piston rod surrounded by a seal cap and raised and lowered relative to the cylinder; And it may include a stem that is coupled to the piston rod and moves up and down together with the piston rod. Additionally, for example, the pump assembly 120 may include a head portion that is coupled to the top of the stem and receives a pressure operation from the user and discharges the contents to the outside. Additionally, for example, the pump assembly 120 may include a suction pipe extending from the bottom of the cylinder to the inside of the receiving portion 110. However, the structure of the pump assembly 120 is exemplary, and the pump assembly 120 may include all known pump structures.

The discharge unit 200 is coupled to the upper side of the container unit 100 and can discharge the contents contained in the container unit 100 to the outside. For example, when the discharge unit 200 is pressurized, the pump assembly 120 coupled to the bottom of the discharge unit 200 is compressed and decompressed, so the contents contained in the receiving unit 110 are transferred to the discharge unit 200. After being introduced, it can be discharged to the outside.

In an embodiment, the discharge unit 200 may include a nozzle unit 210, a limiting protrusion 220, and a coupling protrusion 230.

The nozzle unit 210 is provided on one side of the discharge unit 200 and penetrates in the longitudinal direction to discharge the contents flowing into the discharge unit 200 to the outside.

The limiting protrusion 220 may limit or allow pressurization of the discharge unit 200. For example, the limiting protrusion 220 is formed to protrude from the inner peripheral surface of the discharge unit 200, and is restricted or allowed to descend depending on the rotational position relative to the guide unit 400 (particularly, the first guide unit 410). It can be. For example, the limiting protrusion 220 rotates within a predetermined range, and its descent is limited by the guide unit 400 (when the elevating part 300 is in the first position) or (when the elevating part 300 is in the second position) (when in position) descent may be permitted by the guide unit 400. When the lowering of the limiting protrusion 220 is restricted, the pressing of the discharge unit 200 may be limited, and when the lowering of the limiting protruding 220 is allowed, the pressing of the discharging unit 200 may be allowed.

The coupling protrusion 230 may receive rotational force from at least a portion of the guide portion 400 (particularly, the second guide portion 420). For example, the coupling protrusion 230 is formed to protrude from the outer peripheral surface of the discharge unit 200, and is located on one side (particularly, the coupling groove 423) of the guide part 400 (particularly, the second guide part 420). can be inserted. Accordingly, the discharge part 200 is at least a part of the guide part 400 (particularly, the second guide part 420) (and/or the lifting part 300 coupled to rotate synchronously with the second guide part 420) ) and can rotate synchronously. However, this coupling structure is an example, and the discharge part 200 is coupled to rotate synchronously with at least a part of the guide part 400 (particularly, the second guide part 420) in addition to the coupling protrusion 230. It may contain a bonding structure.

The lifting part 300 is coupled to the outside of the discharging part 200 to surround at least a portion of the discharging part 200, and can adjust the exposure of the nozzle part 210 while moving up and down according to the rotation operation. The user exposes the nozzle unit 210 to the outside only when he or she wants to use the contents, and shields the nozzle unit 210 through the lifting unit 300 when the contents are not in use, thereby protecting the nozzle unit 210 and the contents. Pollution can be prevented.

For example, the lifting unit 300 can be raised and lowered between the (lower) first position and the (upper) second position according to the rotation operation, and exposes the nozzle unit 210 to the outside at the first position. In the second position, the nozzle unit 210 can be shielded from the outside. At this time, the lower end of the lifting part 300 may be disposed adjacent to the upper end of the receiving part 110 in the first position, and may be spaced apart from the upper end of the receiving part 110 by a predetermined distance in the second position. However, this is an example, and various embodiments may be applied, such as the first position and the second position being described in reverse.

In an embodiment, when the lifting unit 300 is raised or lowered, the lifting unit 300 and the discharge unit 200 may rotate synchronously. For example, the lifting unit 300 is coupled to the discharge unit 200 via at least a part of the guide unit 400 (in particular, the second guide unit 420), but the lifting unit 300 and the guide unit ( As at least a portion of the 400 (in particular, the second guide unit 420) and the discharge unit 200 rotate synchronously, the lifting unit 300 and the discharge unit 200 may rotate synchronously. However, it is not limited to this coupling structure, and various embodiments can be applied, such as coupling the elevating part 300 to the discharge part 200 so as to directly rotate synchronously.

In an embodiment, the lifting unit 300 may include a first lifting unit 310 and a second lifting unit 320.

The first lifting unit 310 can be raised and lowered by rotation and can transmit rotational force to at least a portion of the guide unit 400 (particularly, the second guide unit 420) and/or the discharge unit 200.

For example, the first lifting part 310 may be formed in the form of a tube with the upper and lower sides penetrating, but the shape of the first lifting part 310 is not limited to this.

In an embodiment, the first lifting unit 310 may include an inclined groove 311 and a vertical groove 312.

The inclined groove 311 may guide the lifting unit 300 to go up and down when a rotational operation is applied to the lifting unit 300 . For example, the inclined groove 311 is formed by recessing the inner peripheral surface of the first lifting unit 310 or penetrating to the outer peripheral surface, and may extend from a point of the first lifting unit 310 to have a predetermined inclination. For example, a part of the guide part 400 (in particular, the lifting guide protrusion 411) may be inserted into the inclined groove 311, and when the lifting part 300 rotates, the inclined groove 311 rotates. , the lifting and lowering of the lifting unit 300 may be guided by a part of the guide unit 400 (in particular, the lifting guide protrusion 411) inserted into the inclined groove 311.

The vertical groove 312 may transmit the rotational force of the lifting unit 300 to at least a portion of the guide unit 400 (particularly, the second guide unit 420) and/or the discharge unit 200. For example, the vertical groove 312 is formed by recessing the inner peripheral surface of the first lifting unit 310 or penetrating through to the outer peripheral surface, and may extend in the vertical direction from a point of the first lifting unit 310. For example, a part of the guide part 400 (in particular, the rotation guide protrusion 421) may be inserted into the vertical groove 312, and when the lifting part 300 rotates, the vertical groove 312 rotates. , the rotation of a portion of the guide portion 400 (in particular, the rotation guide protrusion 421) inserted into the vertical groove 312 may be guided.

The second lifting unit 320 is coupled to rotate synchronously with the first lifting unit 310 on the outside of the first lifting unit 310, and can receive the user's rotation operation.

For example, the second lifting unit 320 may be formed in the form of a tube with the top and bottom penetrating so as to surround at least a portion of the first lifting unit 310, but the shape of the second lifting unit 320 is limited to this. That is not the case.

In an embodiment, the second lifting unit 320 may include a receiving groove 321 . The receiving groove 321 is formed by recessing at least one area of the upper part of the second lifting part 320, and can accommodate the nozzle part 210 at the second position.

In an embodiment, when the lifting unit 300 is raised and lowered, the receiving groove 321 and the nozzle unit 210 may remain aligned with each other. That is, the relative rotational positions of the nozzle unit 210 and the receiving groove 321 when the lifting unit 300 is in the second position can be maintained even when the lifting unit 300 is in the first position. For example, when the lifting unit 300 is raised and lowered, the receiving groove 321 and the nozzle unit 210 rotate together due to synchronous rotation of the lifting unit 300 and the discharge unit 200, thereby causing mutual alignment. It can be maintained. In this way, since the receiving groove 321 is raised and lowered while maintaining mutual alignment with the nozzle unit 210, the lifting unit 300 can be held in the second position despite the rotation and lifting movements of the lifting unit 300. At this time, the nozzle unit 210 can always be accommodated in the receiving groove 321. In addition, for example, even if the rotational position of the lifting unit 300 changes regardless of the user's rotation operation, the discharge unit 200 rotates synchronously with the lifting unit 300 to form the receiving groove 321 and the nozzle unit 210. ) are still maintained, the content container 1000 can be easily used without arbitrarily changing the assembly structure of the lifting unit 300 and the discharging unit 200, thereby simplifying use. In addition, for example, there is no need to assemble with the relative rotational positions of the nozzle unit 210 and the receiving groove 321 precisely aligned, but only the initial alignment of the nozzle unit 210 and the receiving groove 321 is adjusted. Since assembly is sufficient, assembly can be simplified.

The guide unit 400 is coupled to the inside of the lifting unit 300, guides the lifting and lowering of the lifting unit 300, and can transmit the rotational force of the lifting unit 300 to the discharge unit 200. At least a portion of the guide unit 400 may be exposed to the outside as the elevating unit 300 is placed in the second position.

In an embodiment, the guide unit 400 may include a first guide unit 410 and a second guide unit 420.

The first guide unit 410 may guide the lifting unit 300 to go up and down when the lifting unit 300 rotates.

For example, the first guide portion 410 includes a coupling portion coupled to the container portion 100 on the inside; an inner wall connected to the outside of the coupling portion; It may include an outer wall spaced apart from the inner wall and a connection part connecting the inner wall and the outer wall. The shape of the first guide part 410 is an example, and the first guide part 410 may include any type of structure to perform the function of the present invention.

In an embodiment, the first guide unit 410 may include a lifting guide protrusion 411. For example, the lifting guide protrusion 411 may protrude from the outer peripheral surface of the first guide portion 410 and may be inserted into the inclined groove 311. According to this, when the lifting unit 300 rotates, the lifting guide protrusion 411 rotates relative to the inclined groove 311, and the lifting unit 300 can be raised and lowered. Specifically, when the lifting unit 300 rotates, the inclined groove 311 rotates, and one side of the lifting unit 300 forming the inclined groove 311 is a lifting guide protrusion inserted into the inclined groove 311. As the pressure is applied upward or downward by 411, the lifting unit 300 can move up and down.

In an embodiment, the first guide portion 410 includes an elastic piece 412, and the lifting guide protrusion 411 may be formed on the outer peripheral surface of the elastic piece 412. For example, the elastic piece 412 may extend upward from the first guide portion 410, particularly a region of the outer peripheral surface of the outer wall, and may be elastically deformed inward upon application of an external force. In this case, when the first guide part 410 and the first lifting part 310 are pressed toward each other for assembly, the elastic piece 412 is elastically deformed in the inward direction, and then the lifting guide protrusion 411 and When the inclined grooves 311 are aligned at positions corresponding to each other, the elastic piece 412 recovers its elasticity, so that the lifting guide protrusion 411 is inserted into the inclined groove 311 to engage the first guide portion 410 and the first lifting guide. Part 310 may be combined.

For example, in order to guide the elastic deformation of the elastic piece 412 and the insertion of the lifting guide protrusion 411, an insertion guide surface 311-1 may be formed at the lower end of the inclined groove 311. For example, the insertion guide surface 311-1 extends downward from the lower end of the inclined groove 311 and may be formed to be inclined toward the outer bottom. With the lifting guide protrusion 411 aligned on the insertion guide surface 311-1, when the first guide part 410 and the first lifting part 310 are pressed toward each other for assembly, the lifting guide protrusion ( 411) is pressed inward by the insertion guide surface 311-1, so that the elastic deformation of the elastic piece 412 can be guided. In addition, when the lifting guide protrusion 411 enters the lower end of the inclined groove 311, the elastic piece 412 recovers its elasticity, and the lifting guide protrusion 411 is inserted into the inclined groove 311, the insertion guide surface 311 Separation of the lifting guide protrusion 411 can be prevented by the end of -1).

In an embodiment, the first guide unit 410 may control whether to allow the discharge unit 200 to be pressurized. For this purpose, for example, a first movement groove 413 and a second movement groove 414 may be formed at the top of the first guide part 410, particularly at the top of the inner wall. For example, the first moving groove 413 is formed along the circumferential direction in one area of the upper part of the first guide part 410, and the second moving groove 414 is formed from one area of the first moving groove 413. An incision may be formed in a vertical direction. The limiting protrusion 220, particularly the lower end of the limiting protrusion 220, may be inserted into the first movement groove 413. The limiting protrusion 220 may rotate along the first moving groove 413 when the discharge unit 200 rotates.

In an embodiment, when the limiting protrusion 220 moves along the first moving groove 413, the lower end of the limiting protruding 220 is positioned at the bottom of the first guide portion 410 that forms the lower end of the first moving groove 413. When in contact with one surface, the downward movement of the limiting protrusion 220 may be restricted. If the downward movement of the limiting protrusion 220 is restricted, the pressure of the discharge unit 200 may be limited. For example, when the lifting unit 300 is in the second position, or when the lifting unit 300 deviates from the first position, the downward movement of the limiting protrusion 220 may be restricted. That is, if the lifting unit 300 leaves the completely lowered state, the pressurization of the discharge unit 200 may be limited.

In an embodiment, when the limiting protrusion 220 rotates and moves along the first moving groove 413 and is aligned with the upper side of the second moving groove 414, downward movement of the limiting protruding 220 may be permitted. . If downward movement of the limiting protrusion 220 is permitted, pressurization of the discharge portion 200 may be permitted. For example, when the lifting unit 300 is in the first position, the limiting protrusion 220 may be allowed to move downward. That is, when the lifting unit 300 is completely lowered, pressurization of the discharge unit 200 can be permitted.

In an embodiment, the first guide portion 410 may include at least one fitting groove 415. The fitting groove 415 may allow the second guide part 420 to be fitted into the first guide part 410 to enable relative rotation. For example, the fitting groove 415 may extend for a predetermined length (in the circumferential direction) along the inner peripheral surface of the first guide portion 410, particularly the inner peripheral surface of the outer wall, and the second guide portion 420 is located in the fitting groove 415. ) (in particular, the fitting protrusion 422) may be inserted. However, this coupling structure is an example, and the first guide part 410 may include various known coupling structures that are coupled to the second guide part 420 so as to be relatively rotatable in addition to the fitting groove 415.

The second guide unit 420 may transmit the rotational force of the elevating unit 300 to the discharge unit 200. For example, the first guide part 410 and the second guide part 420 are coupled to enable relative rotation, but the lifting part 300 is coupled to rotate synchronously with the second guide part 420, and the second guide The unit 420 may be coupled to rotate synchronously with the discharge unit 200. Due to this, the rotational force of the lifting unit 300 may be transmitted to the discharge unit 200 via the second guide unit 420.

For example, the second guide part 420 may be formed to penetrate up and down and be inserted between the inner wall and the outer wall of the first guide part 410. The shape of the second guide part 420 is an example, and the second guide part 420 may include any type of structure to perform the function of the present invention.

In an embodiment, the second guide part 420 may include a rotation guide protrusion 421, an insertion protrusion 422, and a coupling groove 423.

The rotation guide protrusion 421 may, for example, protrude from the outer peripheral surface of the second guide portion 420 and be inserted into the vertical groove 312. According to this, when the lifting unit 300 rotates, the rotation guide protrusion 421 moves along the vertical groove 312 and the second guide unit 420 can rotate. Specifically, when the lifting unit 300 rotates, the vertical groove 312 rotates. One side of the lifting unit 300 forming the vertical groove 312 is a rotation guide protrusion inserted into the vertical groove 312. As 421 is pressed in the lateral direction, the second guide portion 420 may be rotated.

The fitting protrusion 422 may allow the second guide part 420 to be relatively rotatably fitted to the first guide part 410 . For example, the fitting protrusion 422 is formed on the outer peripheral surface of the second guide part 420 and may be inserted into the fitting groove 415. In this case, as the fitting protrusion 422 moves along the fitting groove 415, the first guide part 410 and the second guide part 420 may rotate relative to each other. However, this coupling structure is an example, and the second guide part 420 may include various known coupling structures that are rotatably coupled to the first guide part 410 in addition to the fitting protrusion 422.

The coupling groove 423 transmits the rotational force of the second guide unit 420 to the discharge unit 200, so that the second guide unit 420 causes the discharge unit 200 to rotate synchronously. For example, at least one coupling groove 423 is provided on the inner peripheral surface of the second guide portion 420, and a coupling protrusion 230 may be inserted into the coupling groove 423. When the second guide part 420 rotates due to the rotation of the lifting part 300, the discharge part 200 may be rotated by the coupling of the coupling groove 423 and the coupling protrusion 230. However, this coupling structure is an example, and the second guide portion 420 may include various known coupling structures that are coupled to rotate synchronously with the discharge portion 200 in addition to the coupling groove 423.

The content container 1000 according to FIGS. 1 to 6 is an example, and various configurations may be applied depending on the embodiment to which the present invention is applied. For example, the inclined groove 311 and the vertical groove 312 are formed in the first lifting part 310, the lifting guide protrusion 411 is formed in the first guide part 410, and the rotation guide protrusion 421 ) and the engaging groove 423 are shown to be formed in the second guide portion 420, and the engaging protrusion 230 is shown to be formed in the discharge portion 200, but the inclination groove 311 and the lifting and lowering protrusions are not limited thereto. The position of the guide protrusion 411 is reversed, the positions of the vertical groove 312 and the rotation guide protrusion 421 are reversed, or the positions of the coupling groove 423 and the coupling protrusion 230 are reversed, etc. It is obvious that the embodiments of the present invention may be changed, and even if they are changed, the same effect as the present invention will be achieved.

Figure 7 is a diagram for explaining the operation of the content container according to an embodiment of the present invention, Figure 8 is a diagram for explaining the operation of the first guide part and the lifting part according to an embodiment of the present invention, and Figure 9 is a diagram for explaining the operation of the content container according to an embodiment of the present invention. This is a diagram for explaining the operation of the lifting unit and the second guide unit according to an embodiment of the present invention, and Figure 10 is a drawing for explaining the operation of the second guide unit and the discharge unit according to an embodiment of the present invention. Specifically, in FIGS. 8 to 10, (a) shows the state at the first position, and (b) shows the state at the second position.

Referring to FIGS. 7 to 10 , when the lifting unit 300 is located in the first position, the nozzle unit 210 may be exposed to the outside, and the limiting protrusion 220 may be located on the upper side of the second moving groove 414. By aligning with , pressurization of the discharge portion 200 may be permitted. When the discharge unit 200 is pressurized, the contents contained in the container unit 100 may be discharged to the outside through the nozzle unit 210.

If the lifting unit 300 is rotated in this state, the lifting unit 300 can be raised by the guide unit 400. Specifically, when the lifting unit 300 is rotated, the lifting guide protrusion 411 of the first guide unit 410 rotates relative to the inclined groove 311 of the first lifting unit 310, and the lifting unit 300 ) may rise. More specifically, the inclined groove 311 is rotated by the rotation of the lifting unit 300, and one side of the lifting unit 300 forming the inclined groove 311 is a lifting guide protrusion inserted into the inclined groove 311. As the upward pressure is applied by 411, the lifting unit 300 can rise.

When the lifting unit 300 rotates and goes up and down, the rotational force of the lifting unit 300 is transmitted to the discharge unit 200 via the guide unit 400, so that the lifting unit 300 and the discharge unit 200 rotate synchronously. can do. Specifically, when the lifting part 300 is rotated, the rotation guide protrusion 421 of the second guide part 420 moves along the vertical groove 312 of the first lifting part 310, and the second guide part 420 ) rotates, and the discharge unit 200 can rotate by coupling the coupling groove 423 of the second guide part 420 with the coupling protrusion 230 of the discharge unit 200. More specifically, the vertical groove 312 rotates by the rotation of the lifting unit 300, and one side of the lifting unit 300 forming the vertical groove 312 is a rotation guide protrusion inserted into the vertical groove 312. As 421 is pressed in the lateral direction, the second guide portion 420 may be rotated. As the lifting unit 300 and the discharge unit 200 rotate synchronously in this way, the nozzle unit 210 and the receiving groove 321 can rotate while maintaining alignment.

In this way, when the lifting unit 300 deviates from the first position by rotation, the limiting protrusion 220 is not aligned with the upper side of the second moving groove 414, and accordingly, the first moving groove 413 moves the limiting protrusion 220. Since the downward movement of the limiting protrusion 220 is restricted, the pressure of the discharge unit 200 may be limited.

When the lifting unit 300 finally moves to the second position by rotation, the nozzle unit 210 can be accommodated in the receiving groove 321 and shielded from the outside, thereby preventing contamination of the nozzle unit 210. It can be.

The operation of the content container 1000 according to FIGS. 7 to 10 is an example, and various methods may be applied depending on the embodiment to which the present invention is applied.

As described above, the optimal embodiments are disclosed in the drawings and specifications. Although specific terms are used here, they are used only for the purpose of explaining the present invention and are not used to limit the meaning or scope of the present invention described in the claims. Therefore, those skilled in the art will understand that various modifications and other equivalent embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the attached patent claims.

100: container part 110: receiving part
120: Pump assembly 200: Discharge portion
210: nozzle part 220: limiting protrusion
230: Combined protrusion 300: Elevating portion
310: first lifting unit 311: inclined groove
311-1: Insertion guide surface 312: Vertical groove
320: second lifting unit 321: receiving groove
400: Guide unit 410: First guide unit
411: Elevating guide protrusion 412: Elastic piece
413: first mobile home 414: second mobile home
415: Fitting groove 420: Second guide part
421: Rotation guide protrusion 422: Fitting protrusion
423: Coupling groove 1000: Content container

Claims (10)

As a container for contents,
A container portion that accommodates the contents;
a discharge unit coupled to the upper side of the container unit and provided with a nozzle unit for discharging the contents; and
A lifting part coupled to the outside of the discharging part to surround at least a portion of the discharging part and adjusting the exposure of the nozzle part by moving up and down between a first position and a second position according to a user's rotation operation,
When the elevating part is raised and lowered, the discharge part rotates synchronously with the elevating part. According to claim 1,
A receiving groove is provided at the upper end of the lifting unit to accommodate the nozzle unit at the second position,
When the lifting unit is raised/lowered, the receiving groove and the nozzle unit rotate together due to synchronous rotation of the lifting unit and the discharge unit, thereby maintaining mutual alignment. According to claim 1,
It is coupled to the inside of the elevating part and further includes a guide part that guides the elevating part of the elevating part,
At least one lifting guide protrusion is provided on the outside of the guide part, and at least one inclined groove into which the lifting guide protrusion is inserted is provided on the inside of the lifting part,
When a rotational operation is applied to the lifting unit, the lifting guide protrusion relatively rotates along the inclined groove, and the lifting unit moves up and down. According to claim 3,
The guide unit includes: a first guide unit provided with the lifting guide protrusion; And a second guide part that rotates relative to the first guide part inside the first guide part and is coupled to rotate synchronously with the lifting part and the discharging part, and transmits the rotational force of the lifting part to the discharging part. courage. According to claim 4,
At least one fitting groove is formed along the inner peripheral surface of the first guide portion extending a predetermined length,
At least one fitting protrusion is formed on the outside of the second guide part to be inserted into the fitting groove,
As the fitting protrusion moves along the fitting groove, the first guide part and the second guide part rotate relative to each other. According to claim 4,
At least one rotation guide protrusion is provided on the outside of the second guide part,
At least one vertical groove is provided inside the lifting unit into which the rotation guide protrusion is inserted,
When the lifting unit rotates, the rotation guide protrusion moves along the vertical groove and the second guide unit rotates. According to claim 4,
At least one coupling groove is provided on the inside of the second guide part,
At least one coupling protrusion is provided on the outside of the discharge unit and is inserted into the coupling groove,
When the second guide part is rotated by rotation of the lifting part, the discharge part is rotated by engagement of the coupling groove and the coupling protrusion. According to claim 3,
The lifting unit includes: a first lifting unit provided with the inclined groove; and a second lifting unit coupled to the outside of the first lifting unit to rotate synchronously with the first lifting unit and receiving the rotation operation. According to claim 3,
The container portion includes a receiving portion that accommodates the contents; and a pump assembly provided between the receiving part and the discharging part, compressing and decompressing when the discharging part is pressurized, and moving the contents toward the discharging part. According to clause 9,
At least one limiting protrusion is provided on the inside of the discharge portion,
A first moving groove is formed in an upper area of the guide part into which the limiting protrusion is rotatably inserted along the circumferential direction, and a second moving groove is cut in a vertical direction from one area of the first moving groove,
When the limiting protrusion is aligned with the upper side of the second moving groove in the first position, pressurization of the discharge portion is permitted.

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