The disclosed technology is directed towards a cosmetic compact with paper or polyurethane labeling.
Cosmetic compacts are used to store cosmetic materials such as eyeshadow, blush, concealer, etc. These compacts can have two parts: a body and a cover affixed to the body via a plastic hinge. In many cases, the body and the cover are formed from plastics using conventional injection molding techniques. During this process, the body and cover are molded to include protrusions for forming a first hinge portion and a second hinge portion, respectively. These hinge portions are married to one another to form a final compact product. These hinges, however, are prone to breaking as these plastic hinges break when under relatively little stress. When stored in a women's purse, the damage to the items inside the purse when the hinge breaks is often disastrous.
Also, during conventional manufacturing processes, the pieces of the compact are molded and then assembled. If a customer wants to add labeling to the compact, the labeling is performed as an additional step, after assembly, which increases the cost of the final compact product considerably.
The disclosed technology is directed towards a cosmetic compact that includes a spine with extensions. The spine allows the cosmetic compact to have an unlocked position and a locked position. In the unlocked position, pans that hold cosmetic products can be slid in to and out of an opening of the cosmetic compact. In the locked position, the extensions can be fixedly secure to the cosmetic compact for securing the pans within the cosmetic compact without the need of any adhesive materials.
In one implementation, a cosmetic compact can comprise: a hinge, the hinge including a spine having at least two extensions and at least two protrusions extending from the at least two extensions; a base, the base including at least two receivers and at least one opening configured to receive at least one pan; and a cover, wherein the cover and the base are connected to one another via the hinge, wherein, in a locked position, the extensions are configured to wrap around the base and the at least two protrusions are configured to be removably locked into the at least two receivers thereby securing the at least one pan within the at least one opening, and wherein, in an unlocked position, the at least two protrusions are configured to be removed from the at least two receivers thereby providing access to the at least one opening.
In some implementations, the cosmetic compact can further comprise: an outer wrap material, wherein the cover, the base and the spine are affixed to the outer wrap material. In some implementations, the outer wrap material can have a length greater than a length of the cover, the base and the spine. In some implementations, spacing can created between (1) the cover and the spine and (2) the base and the spine. In some implementations, the spacing can allow the hinge to movably connect the base to the cover.
In some implementations, the hinge can further include an outer spine wrap, wherein the outer spine wrap is adhered to the spine. In some implementations, the hinge can further include an inner spine wrap, wherein the inner spine wrap is adhered to the spine.
In some implementations, the cover and the base can include magnets for magnetically securing the cover to the base when the cosmetic compact is in a closed position. In some implementations, the base can include a platform and a bottom panel that are adhered to one another to form the base. In some implementations, the platform can include well openings. In some implementations, the bottom panel can include dividers, the dividers forming individual compartments for the at least one pan. In some implementations, the bottom panel can include ridges for raising the at least one pan.
In some implementations, the base can include a soft block for limiting movement of the at least one pan when loaded and locked into the base. In some implementations, the base can include a hard block for limiting movement of the at least one pan when loaded and locked into the base.
In some implementations, the cover can include a frame and a top panel that are adhered to one another to form the cover. In some implementations, the cover can further include a mirror. An advantage of the disclosed cosmetic compact is that the cosmetic compact can be assembled with outer wrap material being incorporated into the assembly process. The cosmetic compact also allows pans holding cosmetic material to be easily replaced or interchanged. Another advantage is a hinge that is more durable and can be designed to control an opening angle of an open compact.
The disclosed technology relates to a cosmetic compact with labeling incorporated into the cosmetic compact during assembly. This can be achieved by having a cosmetic compact 10 that includes a top panel 12, a bottom panel 14, a platform 16, a mirror frame 18, mirror 20, spine wrap 22, a spine 24, outer wrap material 26 and magnets 28, 30, as shown in
In some implementations, the top panel 12, the bottom panel 14, the platform 16, the mirror frame 18 and the spine 24 can be manufactured using injection molding. Injection molding is a manufacturing process for producing parts by injecting material into a mold. Injection molding can be performed with a host of materials, including metals, (for which the process is called die-casting), glasses, elastomers, confections, and most commonly thermoplastic and thermosetting polymers. After a product is designed, molds are made from metal, usually either steel or aluminum, and precision-machined to form the features of the desired part. Material for the part is (mixed then) fed into a heated barrel (hopper) and forced into a mold cavity through an injection gate, where it cools and hardens to the configuration of the cavity. Injection molding is widely used for manufacturing a variety of parts. Advances in 3D printing technology, using photopolymers which do not melt during the injection molding of some lower temperature thermoplastics, can be used for some simple injection molds. Parts to be injection molded must be very carefully designed to facilitate the molding process; the material used for the part, the desired shape and features of the part, the material of the mold, and the properties of the molding machine must all be considered. The versatility of injection molding is facilitated by this breadth of design considerations and possibilities.
As described above and shown in
The sidewalls 8a-c of the platform 16 can be slightly longer than the depth of the wells 16a-h, as shown in
In some implementations, sidewall 8b of the platform 16 can include an indent 15 as shown in
The bottom panel 14 can be flat and have a rectangular shape but other shapes and sizes are contemplated. The bottom panel 14 can also include sealing seams 15a-b. The bottom panel 14 can be sized so that it fits within the sidewalls 8a-c of platform 16.
As shown in
The mirror frame 18 can be formed with an opening 21 for receiving a mirror 20. The mirror 20 can be placed within the opening 21 and in some cases adhered to the top panel 12 with an adhesive; however, other adhesive methods are contemplated. The mirror frame 18 can also have a well instead of an opening, and the mirror 20 can be adhered to the bottom of the well of the mirror frame 18.
The spine 24 can be adhered to a spine wrap 22 with an adhesive. In some implementations, the spine 24 and the spine wrap 22 can be laminated together, and then adhered to the outer wrap material 26 thereby forming a hinge 25, as shown in
In some implementations, as shown in
In other implementations, as shown in
The mirror frame 18 and the platform 16 can be fitted with magnets 28, 30. Magnets 30 can be secured to the mirror frame 18 within recesses located on the mirror frame 18 and magnets 28 can be secured to the platform 16 within recesses on a ledge of the platform 16. The magnets can be adhered with heat melt glue, but other securement methods are contemplated. These magnets 28, 30 are capable of magnetically securing the compact 10 in a closed position when not in use. It also allows the top cover 11 (
Outer wrap material 26, e.g., paper, plastics, polyurethane (PU), fabrics, metals, or foils can be adhered to an outer surface of the top cover 11 (
In some implementations, the outer wrap material 26 can be pre-cut to size so that it has the same width as the top panel 12, bottom panel 14 and spine 24. The outer wrap can have a length to accommodate a combined length of the top panel 12, bottom panel 14 and spine 24. The outer wrap can also have a space between the spine and top panel and a space between the spine and bottom panel wherein the spaces allows room for the cosmetic compact 10 to open and close.
During assembly, the top panel 12, the spine 24 and the bottom panel 14 can be glued to the outer wrap material 26 with an adhesive and the edges of the outer wrap 26a and 26b can be folded over to the indentations of the Spine 24a and 24b and glued with an adhesive. Step 1. Magnets 28 and magnets 30 can be glued to the platform 16 and mirror frame 18, respectively. Step 2.
The spine wrap 22 can be glued over the spine 24. Step 3. (In some implementations, the spine wrap 22 and spine 24 can be adhered to each other in a separate step and the combination can be glued to the outer wrap material 26 as a single piece.)
The platform 16 can be adhered to the bottom panel 14. Step 4. More specifically, as show in
The mirror frame 18 can be adhered to the top panel 12. Step 5. More specifically, as show in
The mirror 20 can be glued within the mirror frame (Step 6) and a dust cover 32 can be placed over the platform 16 (Step 7). Once these steps (Steps 1-7) are completed, the cosmetic compact can be folded closed and packaged for shipping. Please note, that the order of these steps are for illustrative purposes as these steps can be performed in several different orders and combinations.
As shown in
In some implementations, the top panel 212, the bottom panel 214, the platform 216, the mirror frame 218 and the spine 224 can be manufactured using injection molding, as described above.
As shown in
The sidewalls 208a-d of the platform 216 can be slightly longer than the depth of the wells 216a-c so as to accommodate the bottom panel 214 as will be described more fully below. In some implementations, sidewall 208d (
One of the sidewalls 208b of the platform 216 can also include an indent 215 as shown in in
The bottom panel 214 can be flat having a rectangular shape but other shapes are contemplated. The bottom panel 214 can also include sealing seams 215a and 215b. The bottom panel 214 can be sized so that it fits within the sidewalls 208a-c of platform 216.
As shown in
The mirror frame 218 can be formed with an opening 221 for receiving a mirror 220. The mirror 220 can be placed within the opening 221 and adhered to the top panel 212 with an adhesive; however, other adhesive methods are contemplated. The mirror frame 218 can also have a well instead of an opening, and the mirror 220 can be adhered to the bottom of the well in the mirror frame 218.
The spine 224 can be adhered to a spine wrap 222 with an adhesive and form part of a hinge 225 (
The hinge 225 can also include angle control tabs 219 used to restrict the compact from fully opening. The angle control tabs 219 allow the cosmetic compact to open at a specific opening range as predetermined, e.g. 100 to 140 degrees. The angle control tabs 219 can be secured with placement openings 201 on the spine 224 and the top panel 212 (
The mirror frame 218 and the platform 216 can also be fitted with magnets 228, 230. Magnets 230 can be secured within recesses on frame 218 and magnet 228 can be secured within recesses on a ledge of the platform 216. The magnets can be adhered with heat melt glue, but other securement methods are contemplated. These magnets 228, 230 are capable of magnetically securing the compact 200 in a closed position when not in use while the top cover 211 (
An outer wrap material 226 e.g. paper, plastics, polyurethane, fabrics, metals, or foils can be adhered to an outer surface of the top cover 211, the cosmetic holder 217 and the hinge 225 as a single piece after assembly. In other implementations, the outer wrap material 226 can be adhered in one or more pieces. The outer wrap material 226 can also be decorated with lenticular prints 238 for marketing and advertising purposes.
In some implementations, the outer wrap material 226 can be pre-cut to size so that it has the same width as the top panel 212, bottom panel 214 and spine 224. The outer wrap can have a length to accommodate a combined length of the top panel 212, bottom panel 214 and spine 224. The outer wrap can also have a space between the spine and top panel and a space between the spine and bottom panel wherein the spaces allows room for the cosmetic compact 22 to open and close.
During assembly, the top panel 212, the spine 224 and the bottom panel 214 can be glued to the outer wrap material 226 with an adhesive and the edges of the outer wrap 226a and 226b can be folded over to the indentations of the spine 224 glued with an adhesive. Step 1. Magnets 228 and magnets 230 can be glued with the recesses of the platform 216 and mirror frame 218, respectively. Step 2.
Angle control tabs can be glued within recesses 201 on the top panel 212 and the spine 224. Step 3. The spine wrap can be adhered over the spine 224. Step 4. The posts 217 of the spine 224 are snap fitted with recesses 250 of the platform 216. Step 5.
The platform 216 is then fitted to and adhered to the bottom panel 214. Step 6. More specifically, the bottom panel 214 can be placed within the sidewalls 208a-d of the platform 216 so that the sidewalls 208a-c hide the edges of the outer wrap material 226. This placement allows the sealing seams 215a-b to be adjacent and touching the walls of well 216c. A sonic weld can then be performed to weld sealing seam 215a and 215b to well 216c. Other adhesive mechanisms are contemplated, e.g., adhesives. This step (Step 6) forms the cosmetic holder 217 (
The mirror frame 218 can be adhered to the top panel 212. Step 5. More specifically, the top panel 212 can be placed within the sidewalls 209a-d of mirror frame 218 so that the sidewalls 209a, c-d, hide the edges of the outer wrap material 226. This placement allows sealing seams 213a-d of are adjacent and touching the sidewalls 209a-d of mirror frame 218 so that a sonic weld can be performed to weld sealing seams 213-d to the sidewalls 209a-d of mirror frame 218. This step (Step 7) forms a top cover 211 (
The mirror 220 can then be glued within the mirror frame 218 (Step 8), a dust cover can be placed over the platform (Step 9) and a lenticular print 238 can be adhered to the top of the compact 200. Once these steps (Steps 1-7) are completed, the cosmetic compact can be folded closed and packaged for shipping. Please note, that the order of these steps are for illustrative purposes as these steps can be performed in a number of different combinations.
In another implementation, shown in
In another implementation, as shown in
The cosmetic compact 400 can include a top panel 405, a bottom panel 411, a platform 421, a spine 407, a mirror frame 416, a mirror 460, an inner spine wrap 419, an outer spine wrap 403, an outer wrap material 401, magnets 425, 426, pans 450a-e, a soft block 415, a hard block 428 and protective paper 427, as shown in
In some implementations, the top panel 405, the bottom panel 411, the platform 421, the mirror frame 416, the spine 407, and the hard block 428 can be manufactured using injection molding. Injection molding is a manufacturing process for producing parts by injecting material into a mold. Injection molding can be performed with a host of materials, including metals, (for which the process is called die-casting), glasses, elastomers, confections, and most commonly thermoplastic and thermosetting polymers. After a product is designed, molds are made from metal, usually either steel or aluminum, and precision-machined to form the features of the desired part. Material for the part is (mixed then) fed into a heated barrel (hopper) and forced into a mold cavity through an injection gate, where it cools and hardens to the configuration of the cavity. Injection molding is widely used for manufacturing a variety of parts. Advances in 3D printing technology, using photopolymers which do not melt during the injection molding of some lower temperature thermoplastics, can be used for some simple injection molds. Parts to be injection molded must be very carefully designed to facilitate the molding process; the material used for the part, the desired shape and features of the part, the material of the mold, and the properties of the molding machine must all be considered. The versatility of injection molding is facilitated by this breadth of design considerations and possibilities.
The platform 421 can be adhered to the bottom panel 411 thereby forming a base 30 of the cosmetic compact 400. The mirror frame 416 can be adhered to the top panel 405 thereby forming a cover 429 of the cosmetic compact 400. The cover 429 and the base 430 can be connected to each with a hinge 436, as shown in
As shown in
As shown in
The pans 450a-e can be manufactured using molding methods known in the art using an injection material, e.g., plastic. The pans 450a-e can be individually molded, and each pan can be configured to retain cosmetic materials. In some implementations, the pans can be formed in a single unit having one or more wells (not shown). The pans 450a-e can be rectangular but other shapes are contemplated. In some implementations, the pans can have a length, width and height that is capable of fitting within the openings 454a-e of the base 30. The bottom panel 411 also has ridges 413 to raise pans 450a-e, as shown in
Additionally, in a rear portion of the openings 454a-e, a soft block 415 (
In some implementations, sides 21a, 21c of the platform 421 can have indents 422a-b for partially receiving the extensions 408a-b of the spine 407 when in a locked position. In some implementations, sidewall 421b of the platform 421 can include an indent 423 as shown in
As shown in
As shown in
The mirror frame 416 can be formed with an opening 418 for receiving a mirror 460. The mirror 460 can be placed within the opening 418 and in some cases adhered to the top panel 405 with an adhesive; however, other attachment methods are contemplated.
The mirror frame 416 and the platform 421 can be fitted with magnets 425, 426. Magnets 425 can be secured to the mirror frame 416 within recesses located on the mirror frame 416 and magnets 426 can be secured to the platform 421 within recesses on a ledge of the platform 421. The magnets can be attached with heat melt glue, but other securement methods are contemplated. These magnets 425, 426 are capable of magnetically securing the compact 400 in a closed position when not in use. It also allows the mirror frame 416 and the platform 421 to provide a tight fit of contact for the cosmetic compact 400 when in a closed position so that cosmetic material does not escape the cosmetic compact 400 when not in use. In some implementations, a protective cover 427 (
In some implementations, as shown in
That is, the extensions 408a-b are bendable at creases 458a-b and can wrap around the sides of the base 430 and the protrusions 409, which can be, e.g., snap-in/snap-out connectors, can be locked into the receivers 452a-b of the platform 421. Additionally, the spine 407 can be adhered to an inner spine wrap 419 using an adhesive. In some implementations, the inner spine wrap 419 can include openings 420 for receiving the pressure tabs of the spine.
In some implementations, the spine 407 and an outer spine wrap 403 can be laminated together, and then adhered to the outer wrap material 401 thereby partially forming the hinge 436, as shown in
In some implementations, the outer wrap material 401 (
In some implementations, the outer wrap material 401 can be pre-cut to size so that it has the same width as the top panel 405, bottom panel 411 and spine 407 (minus the extensions). The outer wrap 401 can have a length to accommodate a combined length of the top panel 405, bottom panel 411 and spine 407. The outer wrap 401 can also have a space between the spine 407 and top panel 405 and a space between the spine 407 and bottom panel 411 wherein the spaces allows room for the cosmetic compact 400 to open and close.
During assembly, the top panel 405, the spine 407 and the bottom panel 411 can be glued to the outer wrap material 401 with an adhesive. Step 1. Magnets 425 and magnets 426 can be glued to the platform 421 and mirror frame 416, respectively. Step 2.
The outer spine wrap 403 can be glued over the spine 407. Step 3. (In some implementations, the spine wrap 403 and spine 407 can be adhered to each other in a separate step and the combination can be glued to the outer wrap material 401 as a single piece.)
The platform 421 can be adhered to the bottom panel 411. Step 4. More specifically, the bottom panel 411 can be placed within the sidewalls of the platform 421 so that the sidewalls 8a-c hide the edges of the bottom panel 411 and the edges of the outer wrap material 401. This placement allows the sealing seams 412 to be adjacent and touching the walls of platform 421. A sonic weld can then be performed to weld sealing seams 412 to the platform 421. Other adhesive mechanisms are contemplated, e.g., adhesives.
The mirror frame 416 can be adhered to the top panel 405. Step 5. More specifically, the top panel 12 can be placed within the sidewalls 16a-d of mirror frame so that the sidewalls 16a-d hide the edges of the top panel 405 and the edges of the outer wrap material 401. This placement allows sealing seams 6a-d to be adjacent and touching the sidewalls 9a-d of mirror frame 416 so that a sonic weld can be performed to weld sealing seams 6a-d to the sidewalls 9a-d of mirror frame 416. Please note, steps 3-5 can be done one at time or simultaneously.
The mirror 460 can be adhered within the mirror frame 416 with the soft block in place. (Step 6). Once assembled, the pans 450a-e can be loaded into the platform 421. The spine can be moved into a locked position so that the protrusions 409 of the spine 407 can be locked into the receivers 452 and a protective cover 432 can be placed over the platform 421 (Step 7). Once these steps (Steps 1-7) are completed, the cosmetic compact can be folded closed and packaged for shipping. Please note, that the order of these steps are for illustrative purposes as these steps can be performed in several different orders and combinations.
While presently preferred embodiments have been described for purposes of the disclosure, numerous changes in the arrangement can be made by those skilled in the art. Such changes are encompassed within the spirit of the invention.
The foregoing Detailed Description is to be understood as being in every respect illustrative and exemplary, but not restrictive, and the scope of the disclosed technology disclosed herein is not to be determined from the Detailed Description, but rather from the claims as interpreted according to the full breadth permitted by the patent laws. It is to be understood that the embodiments shown and described herein are only illustrative of the principles of the disclosed technology and that various modifications may be implemented by those skilled in the art without departing from the scope and spirit of the disclosed technology. Those skilled in the art could implement various other feature combinations without departing from the scope and spirit of the disclosed technology. Although the embodiments of the present disclosure have been described with specific examples, it is to be understood that the disclosure is not limited to those specific examples and that various other changes, combinations and modifications will be apparent to one of ordinary skill in the art without departing from the scope and spirit of the disclosed technology.
This application is a continuation in part of U.S. patent application Ser. No. 16/146,103 filed Sep. 28, 2018 in which claims priority to U.S. Provisional Application Ser. No. 62/581,993 filed Nov. 6, 2017, both of which are hereby incorporated by reference in their entirety.
Number | Name | Date | Kind |
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6286521 | Joulia | Sep 2001 | B1 |
20090071867 | Au | Mar 2009 | A1 |
20160075475 | Apodaca | Mar 2016 | A1 |
Number | Date | Country | |
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20200275757 A1 | Sep 2020 | US |
Number | Date | Country | |
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62581993 | Nov 2017 | US |
Number | Date | Country | |
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Parent | 16146103 | Sep 2018 | US |
Child | 16816902 | US |