The present application relates to the field of product packaging, in particular to an all-metal center tube core, a cosmetic packaging tube including the center tube core, and a processing method of the center tube core and the packaging tube.
Packaging tube is a carrier of cosmetics such as lipstick, and center tube core is its core component, which generally includes a prong, a bead and a spiral. In order to make the appearance of the product beautiful, the spiral of some product is surrounded by a middle bundle of metal material, or the prong of some products is made of metal material, while most of other components are made by injection molding of polymer materials due to the restrictions of the process. With the demanding of environmental protection, people hope that plastics and other materials can be recycled and reused. As mentioned above, most of the existing packaging tubes are made of metal and plastic, which are always difficult to recycle and reuse.
The present application provides a center tube core made of all metal material, which solves the problem that the traditional center tube core is difficult to be recycled and reused.
The center tube core comprises a prong, a spiral rotatably surrounding the prong and a bead slidably provided in the prong for supporting product, wherein a side wall of the prong is provided with a slide slot extending in an axial direction, an outer wall of the bead is provided with a slide block extending out of the slide slot in a radial direction, and an inner wall of the spiral is provided with a feed thread acting on the slide block, and wherein the prong, the bead and the spiral are all made of metal material.
In the following, a number of alternatives are provided, but not as additional limitations to the above-mentioned general subject matter, and merely as further additions or preference. Without technical or logical contradiction, the alternatives can be combined individually with the above-mentioned general subject matter, or can be combined among them.
Optionally, the metal material is aluminum or aluminum alloy.
Optionally, the prong, the bead and the spiral are all made of the same metal material.
Optionally, a part of a side wall of the bead protrudes radially outwardly to form the slide block.
Optionally, at least two slide blocks are evenly distributed along a circumferential direction of the bead.
Optionally, the slide block is integrally engaged with the feed thread, or a surface of the slide block is provided with one or more ridges that are engaged with the feed thread.
Optionally, the inner wall of the spiral forms the feed thread by cutting.
Optionally, the feed thread is formed by deformation of a tube wall of the spiral.
Optionally, the feed thread comprises a threaded bottom wall and two opposed threaded sidewalls, and an included angle between the threaded sidewall and the threaded bottom wall is 90 degrees to 145 degrees.
Optionally, an inner wall of the bead is provided with a limiting protrusion for engaging the product.
Optionally, a part of a side wall of the bead is cut to form a tab, and the tab is bent radially inward to form the limiting protrusion.
Optionally, separable portions of the tab from the side wall of the bead includes three transverses connected in sequence, respectively:
Optionally, separable portions of the tab from the side wall of the bead includes three transverses connected in sequence, respectively:
Optionally, the bead comprises an inner cylinder and an outer cylinder surrounded one around the other, and wherein an outer wall of the outer cylinder is provided with the slide block.
Optionally, an inner wall of the inner cylinder is provided with axially extending ribs for engaging with the product.
Optionally, the ribs are formed by radially inward depression of a wall of the inner cylinder.
The present application further provides a cosmetic packaging tube comprising the center tube core above, a top cover and a base.
Optionally, the prong comprises a first inner section extending into the spiral and a first operation section located axially outside a bottom end of the spiral, wherein the slide slot is defined in the first inner section, the base is fixedly connected with the first operation section, the spiral is at least partially exposed outside the base, and the exposed portion has a smooth outer wall surface.
Optionally, a positioning step is provided between the first inner section and the first operation section, and the bottom end of the spiral abuts against the positioning step.
Optionally, an outer peripheral surface of the spiral is flush with an outer peripheral surface of the first operation section.
Optionally, a bottom end of the first operation section is provided with a closing plate.
Optionally, an outer wall of the prong is provided with a positioning groove extending in a circumferential direction, and the inner wall of the spiral is provided with a positioning protrusion engaged with the positioning groove.
Optionally, the positioning groove is formed by deformation of a tube wall of the prong.
Optionally, the positioning protrusion is formed by deformation of a tube wall of the spiral.
Optionally, a plurality of positioning protrusions are provided and evenly distributed along a circumferential direction of the spiral.
Optionally, an outer wall of the prong is provided with a positioning groove extending in a circumferential direction, and the inner wall of the spiral is provided with an annular positioning protrusion extending in a circumferential direction and engaged with the positioning groove.
Optionally, the prong comprises a second inner section extending into the spiral and a second operation section located axially outside a top end of the spiral, and wherein the slide slot is defined in the second inner section, the spiral is fixedly connected with the base and is accommodated in the base.
Optionally, an outer wall of the spiral has a deformation corresponding to the feed thread.
Optionally, the second operation section extends into the top cover.
Optionally, the bead is an axially penetrated tubular structure and comprises a product supporting portion and an extension portion distributed in an axial direction of the bead, and wherein the slide block is provided at the extension portion and the tubular structure has a reduced diameter region between the product supporting portion and the extension portion, and the reduced diameter region forms a product stop ring on an inner wall of the tubular structure.
Optionally, the base, the spiral, and the prong are each provided with an avoidance opening corresponding to an inner cavity of the tubular structure.
Optionally, a middle sleeve is fixedly inserted into an opened portion of the base, a gap is defined between the middle sleeve and the spiral in an axial direction of the base, which serves as an axial positioning groove, and a positioning ring is inserted into the axial positioning groove arranged on an outer periphery of the prong.
Optionally, the side wall of the prong protrudes radially outwardly to form the positioning ring.
Optionally, the spiral and the middle sleeve are both in an interference fit with the base.
Optionally, one axial end of the base is provided with an opening for insertion of the prong and the other axial end is provided with a through hole whose periphery is an annular inner flange, and wherein an end of the spiral abuts against the inner flange.
Optionally, the base is made of metal material and has a smooth outer peripheral surface.
The present application also provides a processing method for a center tube core for processing the center tube core as described.
In the application, the center tube core is made of metal material, the product does not need to be disassembled during recycling, and can be recycled directly, with a simple and convenient operation.
In the figures, reference numerals are listed below:
1, prong; 11, slide slot; 12, positioning groove; 13, positioning ring; 14, first inner section; 15, first operation section; 16, positioning step; 17, closing plate; 18, second inner section; 19, second operation section; 2, spiral; 21, feed thread; 211, threaded bottom wall; 212, threaded sidewall; 22, positioning protrusion; 23, annular positioning protrusion; 24, flange; 3, bead; 31, slide block; 301, outer cylinder; 302, inner cylinder; 303, rib; 311, ridge, 32, limiting protrusion, 321, connecting end, 322, free end, 323, first transverse, 324, second transverse, 325, third transverse, 326, fourth transverse, 327, fifth transverse, 328, sixth transverse; 33, supporting portion; 34, extension portion; 35, product stop ring; 4, avoidance opening; 5, base; 51, inner flange; 6, middle sleeve; 61, first insertion portion; 62, second insertion portion; 63, limiting ring; 7, top cover.
The technical solutions according to the embodiments of the present disclosure will be described in combination with the drawings according to the embodiments of the present disclosure. The described embodiments represent some but not all the possible embodiments.
It should be noted that, when a component is “connected” with another component, it may be directly connected to another component or may be indirectly connected to another component through a further component. When a component is “provided” on another component, it may be directly provided on another component or may be provided on another component through a further component.
Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by a person skilled in the art. The terms in the description of the present disclosure are used to describe specific embodiments, and not to limit the present disclosure. The term “and/or” used herein includes any combinations of one or more of the listed options, as well as the combination of all of the listed options.
In one embodiment, as shown in
The axial direction, i.e., the longitudinal direction of the center tube core, is also the direction of moving forth and back of the bead 3 in use, and the radial direction is a direction perpendicular to the axial direction. In use, the spiral 2 is rotated relative to the prong 1 to change the overlapping area of the feed thread 21 and the slide slot 11, so that the bead 3 and the product can move forth and back in the axial direction.
In this embodiment, the prong 1, the bead 3 and the spiral 2 are made of metal, with the same processing, thereby reducing the manufacturing cost and facilitating the recycling. Specifically, the metal material is aluminum or an aluminum alloy.
In one embodiment, as shown in
In one embodiment, as shown in
In order to axially fix the spiral 2 and the prong 1, as shown in
In one embodiment, as shown in
In one embodiment, as shown in
As shown in
In one embodiment, a part of the side wall of the bead 3 projects radially outwardly to form the slide block 31. For example, a portion of the metal tube wall can be drawn outwardly to form the slide block 31. In particular, at least two slide blocks 31 are evenly distributed in the circumferential direction of the bead 3. As shown in
Specifically, in one embodiment, as shown in
There are various ways of forming the feed thread 21, and in one embodiment, the feed thread 21 is formed on the inner wall of the spiral 2 by cutting. In another embodiment, the spiral 2 forms the feed thread 21 by deformation of the tube wall itself.
In particular, in one of the embodiments, the feed thread 21 can be formed by rolling the wall of the spiral 2 in combination of rotation and axial feed.
In particular, in one of the embodiments, the tube having a smooth outer peripheral surface is pressed by a die inside and outside the tube, respectively, so that the inner peripheral surface of the tube forms the feed thread 21.
In one embodiment, as shown in
The product is generally a paste. In order to ensure that the product is firmly fixed in the bead 3, the inner wall of the bead abuts against or is inserted into the paste through a limiting protrusion 32, thereby further preventing the product from sliding along the axial direction.
The pasty product can be pre-molded and then axially loaded into the bead 3, or be molded by injecting the starting material into the bead 3. There are various ways of processing the limiting protrusion 32. For example, the side wall of the bead 3 can be pressed inward in such a way that a part of the side wall is deformed to protrude inward, and the outside of the bead 3 is concaved.
In order to facilitate the axial loading of the pre-cured product into the bead 3, preferably, a part of the side wall of the bead 3 is cut to form a tab, which is bent radially inward to form the limiting protrusion. Specifically, slot(s) can be cut on the metal side wall of the bead 3 along a non-closed path, and then the tab partially surrounded by the slot(s) is pushed inward to form the limiting protrusion 32.
In one embodiment, as shown in
In another embodiment, as shown in
Specifically, as shown in
In one embodiment, as shown in
In another embodiment, as shown in
In this embodiment, the prong 1, the bead 3 and the spiral 2 are all made of metal.
As shown in
In assembly, the base 5 is fixedly connected to the spiral 2, the spiral 2 is integrally received in the base 5, and the second operation section 19 is exposed from the base 5. The base 5 and the spiral 2 are generally connected by an interference fit, although can be connected by bonding or the like.
In an embodiment, as shown in
As shown in
The term of “all-metal” used herein refers to the three main parts, namely, the prong 1, the bead 3 and the spiral 2. Undoubtedly, the center tube core may also include other additional parts, and the material of these additional parts is not strictly limited.
In one embodiment, the base 5 and the top cover 7 are also made of metal and have smooth outer peripheral surfaces.
In one embodiment, the prong 1, the bead 3, the spiral 2 and the base 5 are made of the same metal.
The spiral 2, the prong 1 and the base 5 are each provided with an avoidance opening 4 corresponding to the inner cavity of the tubular structure, and by providing the avoidance opening 4, the product can be loaded into the center tube core from the bottom end.
One axial end of the base 5 is provided with an opening for the insertion of the center tube core, and the other axial end is provided with a through hole whose periphery is an annular inner flange 51 against which the end of the spiral 2 abuts.
A middle sleeve 6 is fixedly inserted into the opening of the spiral 2, and a gap is defined between the middle sleeve 6 and the spiral 2 in the axial direction of the base 5, which serves as an axial positioning groove. A positioning ring 13 is inserted into the axial positioning groove on the outer periphery of the prong 1. The side wall of the prong 1 projects radially outwards to form the positioning ring 13.
As shown in
In one embodiment, the production process of the all-metal center tube core includes: processing the side wall of the bead 3 to form the slide block 31 that protrudes radially outwardly, and forming the inwardly turned tab by cutting the side wall of the bead 3; assembling the bead 3 into the prong 1 with the slide slot 11 on the side wall thereof in such a way that the slide block 31 extends radially out of the slide slot 11; forming the feed thread 21 acting on the slide block 31 on the inner wall of the spiral 2 having a smooth outer peripheral surface; and assembling the prong 1 into the spiral 2 in such a way that the slide block 31 is engaged with the feed thread 21.
In another embodiment, the bead 3 is formed by assembling the outer cylinder 301 and the inner cylinder 302 by interference fit, wherein the outer cylinder 301 is machined at the side wall thereof to form a slide block that protrudes radially outwardly, and the inner cylinder 302 is machined at the side wall thereof to form the rib 303 that is radially recessed.
In another embodiment, a die is used to extrude a tube inside and outside, respectively, so that the inner peripheral surface of the tube forms the feed thread 21, and the outer peripheral surface of the tube forms a deformation corresponding to the feed thread 21.
In one embodiment, as shown in
In another embodiment, as shown in
The present application further provides a process for the cosmetic packaging tube. In one embodiment, the base 5 is fixedly connected with the bottom of the prong 1, the top cover 7 is surrounded around the center tube core. As shown in
In another embodiment, the base 5 is in an interference fit with the spiral 2 such that the spiral 2 is completely received within the base. The mouth of the base 5 is provided with the middle sleeve 6, which is inserted into the base and in an interference fit therewith, and cooperates with the spiral 2 to limit the axial movement of the prong. The top cover 7 surrounds around the exposed part of the center tube core, and cooperates with the base 5 and the middle sleeve 6 to enclose the center tube core in the inner space of the three.
The features described in the above various embodiments may be combined. In order to simplify the descriptions, not all possible combinations of the features in the above embodiments have been described. However, any combinations of the features should be within the scope of the invention as long as no conflict resides between these features. In the case where the features in different embodiments are shown in the same drawing, it may be considered that this drawing discloses a combination of the various embodiments involved.
The above embodiments are only several implementations of the present invention which are described specifically and in detail, without limitation to the scope claimed by the present invention. Those skilled in the art can make various modifications and variations to the embodiments without departing from the spirit and scope of the present invention, and these modifications and variations should fall into the scope claimed by the present invention. Therefore, the scope of protection of the invention patent should be subject to the attached claims.
Number | Date | Country | Kind |
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201910968508.3 | Oct 2019 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2020/098512 | 6/28/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2021/068561 | 4/15/2021 | WO | A |
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Number | Date | Country | |
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20220338607 A1 | Oct 2022 | US |