KR101056819B1 - Hologram panel and manufacturing method thereof - Google Patents

Abstract

PURPOSE: A manufacturing method of a hologram panel is provided to directly form a hologram image concavo-convex in front surface of a single body. CONSTITUTION: Upper molds(210,220) is prepared. The upper mold includes a master panel(220a). The master panel includes an embossing or engraving for forming a hologram image unevenness. A lower mold(230) is prepared. If the upper mold and a lower mode is contacted, a liquid material for molding a hologram panel is inserted in a mold frame(233). If the filling of the material about the mold frame is completed, the filled material is cooled.

Description

Hologram panel and its manufacturing method {HOLOGRAM PANEL AND MANUFACTURING METHOD THEREOF}

The present invention relates to a hologram, in particular, has a very simple configuration in which a hologram image is formed on the front of a single body itself made of TPU, and has excellent flex resistance, corrosion resistance, and abrasion resistance, and the hologram image is excellent even in severe bending or frequent contact with water. The present invention relates to a hologram panel and a method of manufacturing the same, which can be used for a long time in various fields and can be used as an anti-counterfeit product for clothes that must endure extreme bending and strong contact with water when washed.

In general, a hologram is a photograph in which an image looks three-dimensionally like a three-dimensional object and is made by using the principle of holography, and refers to a medium that records interference stripes or image irregularities that reproduce three-dimensional shapes.

The principle of holography is to split the beam from the laser into two, one light shining directly on the screen, and the other light shining on the object we want to see. In this case, the light directly shining on the screen is called a reference beam, and the light shining on the object is called an object beam. Since object light is light reflected from each surface of an object, the phase difference (distance from the surface of the object to the screen) varies depending on the surface of the object. At this time, the unmodified reference light interferes with the object light, and the interference fringe is stored on the screen. Films in which such interference fringes are stored are called holograms.

To reproduce the stored image, the ray used to record must be shot back on the screen plate. The light beam used for reproduction must be exactly the same as the reference light used for recording because only waves with the same frequency as in recording are reproduced in three dimensions, and waves with different wavelengths and phases pass through the stored hologram without any effect. do.

The easiest thing to see around is a hologram on a credit card, which has a reflective hologram to prevent counterfeiting. Therefore, the 3D stereoscopic image expressing the unique pattern of the card can be visually confirmed.

It is also used as a storage medium. Since the hologram records the information of the plane in one point, the entire hologram can be reproduced with a small piece of hologram as if you were looking through the window. The information stored in the hologram is very resistant to contamination or damage and is superior in capacity to other storage media.

Furthermore, if research on a method of reproducing continuous images is conducted, it is possible to produce a film using holograms, and it can be used for medical purposes since the human skeleton structure can be observed in three dimensions. In addition, it can be used in various fields such as architecture and automobile design.

1 is a longitudinal sectional view showing a hologram sticker structure as disclosed in Korean Patent Laid-Open Publication No. 10-2005-0078953 to describe a hologram sticker according to the prior art.

As shown, the hologram sticker according to the prior art has a base film layer 10, a partial release layer 20 and a hologram layer 30 located below the base film layer 10, and the hologram layer 30 It was configured to include a pressure-sensitive adhesive layer 40 formed in the lower portion.

The hologram layer 30 basically includes a metal thin film layer 34 and a concave-convex relief layer 32 formed on the rear surface of the metal thin film layer 34 and into which the holographic image irregularities are inserted. In addition, the hologram layer 30 further includes a coloring primary layer 36 for color effects. As shown in the drawing, the hologram layer 30 is a coloring primary layer 36 and a metal in order from the top. It has a laminated structure comprised of the thin film layer 34 and the hologram uneven engraving layer 32.

According to this configuration, the base film layer 10 is to protect the entire sticker from the outside and to serve as a support of the other layers, it is selected from a plastic film. For example, a polyester film having a thickness of 12 to 75 μm was used.

The partial release layer 20 is formed by applying an organic compound such as cellulose, wax, etc. on the base film layer 10 as described above. At this time, the organic compound forming the partial release layer 20 is applied by using a corrugated uneven roller engraved with a pattern such as letters or figures. The partial release layer 20 may have a thickness of 1.0 μm or less. The partial release layer 20 is separated in the form of a pattern engraved by the uneven roller when the sticker is removed from the product. Accordingly, the partial release layer 20 prevents the sticker from being completely removed from the product to prevent reuse.

The colored primary layer 36 is formed by coating a thermosetting lacquer having a color on the partial release layer 20. In addition, an inorganic compound is vacuum-deposited on the colored primary layer 36 to form a metal thin film layer 34. The inorganic compounds constituting the metal thin film layer 34 are aluminum (Al), silver (Ag), and zinc sulfide (ZnS). , Zinc oxide (ZnO), silicon oxide (SiO 2), and the like. The metal thin film layer 34 may have a thickness of 100 ~ 1000㎛.

The colored primary layer 36 and the metal thin film layer 34 composed of the above-described racker and an inorganic compound serve to improve the glossiness and durability of the sticker.

According to the configuration of the hologram sticker configured as described above, the hologram image irregularities inserted into the holographic uneven corner layer 32 is projected through the metal thin film layer 34 and the coloring primary layer 36, and the holographic image appears in three dimensions. will be.

However, looking at the configuration of the hologram sticker according to the prior art, as described above, the hologram unevenness relief layer 32 into which the holographic image unevenness is inserted has not been used alone, and is always provided with the metal thin film layer 34 by vacuum deposition. I was taking a configuration. Such a configuration is a traditional one that is taken for granted by a hologram product that needs to implement a holographic image, and no attempt has been made to deviate from such a conventional configuration. This problem cannot be solved due to the technical aspect and the fact that it was not easy to move out of the conventional thinking framework in the related industry.

In the holographic product according to the prior art only to describe the technical problem that has not attempted to deviate from the conventional configuration as follows. That is, the uneven stamping layer 32 into which the holographic image irregularities are inserted is made of PC or ABS, and the uneven stamping layer 32 made of such a material itself is easily worn by only weak contact with the outside while the holographic image is damaged. There were becoming fatal issues. Therefore, as a way to solve the above problems due to the lack of wear resistance, the laminated structure in which the metal thin film layer 34 is laminated on the entire surface of the uneven relief layer 32 on which the holographic image irregularities are formed is essential. And such a laminated structure has been taken for granted for a long time as a structure for implementing a holographic image.

However, the metal thin film layer 34 provided for the purpose of protecting the holographic image irregularities is easily corroded when contacted with an external oxide such as air or water. I had no choice but to lose the hologram image easily.

In addition, even when the holographic product according to the prior art is bent, it is inevitable that the hologram image is lost while separation and separation between the uneven stamping layer 32 and the metal thin film layer 34 occur easily.

Therefore, the hologram sticker or hologram product according to the prior art has not been used as an anti-counterfeiting product for clothes that must endure harsh environments such as strong contact with water and frequent bending during washing.

In addition, the hologram sticker or hologram product according to the prior art has a complicated laminated structure composed of several layers to realize a holographic image, and thus, a manufacturing process such as vacuum deposition for forming a metal thin film layer is complicated and a post-treatment process is required. In terms of manufacturing costs and manufacturing time was a significant burden.

In addition, the hologram sticker or the hologram product according to the prior art was almost impossible to make the hologram image and the background have a pure intrinsic color by adding a pure intrinsic color to the uneven marking layer 32 into which the holographic image irregularities are inserted. This is because even if the hologram image irregularities inserted into the uneven corner layer 32 pass through the metal thin film layer 34 formed on the front surface, the color may be unique to the uneven corner layer 32 even though the uneven color may be unique. The interference of the metal thin film layer 34 prevented the obtaining of holographic images and backgrounds with the desired pure intrinsic color. Currently, a method of adding a color to the holographic image to form a colored primary layer 36 coated with a thermosetting lacquer having a color on the entire surface of the metal thin film layer 34 is employed. Pure native colors could not be achieved.

In addition, it was difficult to implement transparent products in the same context as pure native colors. In the case of transparency, but it is implemented in some products, it is known to go through a difficult process. As described above, the hologram product according to the related art has a problem in that it is difficult to easily implement both opaque, transparent, and translucent products.

Accordingly, the present invention has been proposed to solve the conventional problems as described above, the object of the present invention has a simple configuration consisting of a body formed directly on the hologram image in the harsh environment that is severely bent or frequently in contact with water The present invention provides a hologram panel having bending resistance and wear resistance so that the hologram image is not damaged.

In order to achieve the above object, the hologram panel according to the technical concept of the present invention is directly formed on the front surface of the body having a wear-resistant material, so that the holographic image irregularities can be directly viewed from the front without passing through another layer. It is characterized by its technical configuration.

Here, the body may be characterized in that the material having a bending resistance in addition to the wear resistance.

In addition, the body may be made of only one layer on which the holographic image irregularities are formed.

In addition, the body may be characterized in that the material is made of TPU (Thermoplastic Polyurethane) to satisfy the conditions of the materials.

In addition, the body may be characterized in that the color is added.

In addition, the body may be characterized in that the transparent or translucent.

In addition, the hologram panel may be characterized in that the clothing is used to be attached to the clothing.

In addition, the body may be characterized in that it has a thickness of at least 1.5mm or more.

On the other hand, the method for manufacturing a hologram panel according to the present invention comprises the steps of: providing an upper mold having a master panel is formed with an embossed for forming the holographic image irregularities; Providing a lower mold provided to correspond to the upper mold, the lower mold having a forming mold at a position facing the positive and negative of the master panel to mold the hologram panel; Pressurizing and injecting a liquid material for forming a hologram panel in a state where the upper mold and the lower mold are in contact with each other by pressing the mold of the lower mold; When the filling of the material to the mold is completed, it characterized in that the technical configuration consisting of the step of cooling and solidifying the material filled in the mold.

Here, after the solidifying step is completed, the lifting pins in the lower mold may be raised to separate the solidified hologram panel from the mold.

In addition, the hologram panel may be characterized in that the material is flexible and wear-resistant.

In addition, the material of the hologram panel may be characterized in that the TPU (Thermoplastic Polyurethane) satisfying the conditions of the materials.

The hologram panel and its manufacturing method according to the present invention can realize a hologram product with a simple configuration of directly forming holographic image irregularities on the front surface of a single body composed of one layer. As a result, manufacturing costs and time can be greatly reduced.

In addition, the present invention is composed of a TPU (Thermoplastic Polyurethane) material having a bending resistance, wear resistance, corrosion resistance, so that the hologram image is not damaged even in a severe environment that is severely bent or in contact with water, it is possible to use for a long time in a variety of environments, especially laundry This product is suitable as anti-counterfeiting product for clothing.

In addition, since the hologram image is directly implemented by the hologram image irregularities formed on the front surface of the body without passing through the conventional metal thin film layer, the hologram image and the background having pure intrinsic colors can be realized by simply adding a color to the body. .

In addition, the present invention can implement a transparent or semi-transparent product as well as an opaque product without a separate difficult process.

In addition, the present invention can be produced by injection molding simply because a single body consisting of a single layer can be implemented, there is no need to join a plurality of layers or go through a post-treatment process.

In addition, the present invention can be produced simply by press molding because the hologram product can be realized with only a single body composed of one layer.

1 is a longitudinal cross-sectional view of a hologram sticker for explaining the prior art.
2 and 3 are a perspective view of a hologram panel according to the present invention.
4 is a longitudinal cross-sectional view for explaining the configuration of a hologram panel according to the present invention.
Figure 5 is a state of use showing the appearance of the hologram panel according to the invention used as anti-counterfeiting product for clothing.
6 is a longitudinal sectional view for explaining a mold for manufacturing the hologram panel according to the present invention.
7 is a plan view of a lower mold of a mold for manufacturing the hologram panel according to the present invention.
8A to 8D are a series of reference diagrams for explaining a method for manufacturing a hologram panel according to the present invention.
9 is a reference diagram showing a state immediately after the hologram panel according to the present invention is molded.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 and 3 are perspective views of the hologram panel according to the present invention.

As shown, the hologram panel 100 according to the present invention is flexible and flexible, has a bending resistance to withstand bending, and by forming the body 110 from a material having corrosion resistance and abrasion resistance, it is severely bent without a metal thin film layer. The holographic image will not be damaged under severe conditions such as water or water contact.

Therefore, the hologram panel 100 according to the present invention can be used for the purpose of the product which is inevitable to be exposed to the harsh environment, and in particular, the hologram product can be used because of the harsh environment that must withstand severe bending and contact with water during washing. It can be suitably used as an anti-counterfeiting product for clothes that did not exist.

Hereinafter, the structure of the hologram panel by this invention is demonstrated in detail.

4 is a longitudinal cross-sectional view for explaining the configuration of a hologram panel according to the present invention.

As shown, the hologram panel according to the present invention has a unique configuration in which the holographic image irregularities 111 are directly formed on the front surface of a single body 110 made of TPU (Thermoplastic Polyurethane) material.

As such, the present invention has a configuration that completely deviates from the complicated and traditional laminated structure in which a metal thin film layer and a colored primary layer are applied to the entire surface of the uneven angle layer into which the holographic image irregularities are inserted.

That is, as can be seen in the enlarged part of FIG. 4, the present invention provides a unique configuration that completely deviates from the simple but traditional configuration in which the holographic image irregularities 111 are directly formed on the front surface of a single body 110 composed of only one layer. As a result, a product including the hologram image 120 may be implemented.

Here, the secret that the hologram image 120 may not be damaged despite the simple method of directly forming the hologram image irregularities 111 on the single body 110 itself as described above constitutes the body 110 of the present invention. The trick lies in the TPU material used to make this work. That is, the TPU is a material having excellent properties in all of flexural resistance, corrosion resistance, and abrasion resistance due to elasticity, and the hologram image irregularities in the harsh environment such as the hologram panel of the present invention made of the material is severely bent or frequently contacted with water. It is possible for 111 (or hologram image 120) to be used semi-permanently without damage.

For reference, the TPU used as the material of the present invention is an eco-friendly urethane material, and is used in the extrusion field of shoes, automobiles, home appliances, etc., and the extrusion field of hoses, wires, and also in special fields such as medical, adhesive, and leisure. It is known to have excellent properties such as extrusion, injection molding, calender molding, and the like, and has excellent characteristics of friction resistance, bending resistance, oil resistance, weather resistance, and the like.

As such, when the holographic image irregularities 111 are directly formed on a single body 110 made of a TPU material, unlike the conventional hologram stickers or hologram products in which the hologram image 120 is easily damaged, flex resistance, corrosion resistance, and wear resistance Of course, all of them are not easily damaged, as well as a very simple configuration consisting of a single layer is easy to manufacture and does not require a separate process such as a post process. Therefore, it is possible to significantly reduce the time and cost required for the manufacture of the product.

Here, the body 110 of the hologram panel according to the present invention is preferably formed to a thickness of at least 1.5mm. This will be described later, but since the hologram panel of the present invention is manufactured by injection molding by a mold, when the thickness is less than 1.5 mm, the yield decreases, and the likelihood of damage due to severe bending increases. Therefore, by securing the thickness of the body 110 to at least 1.5mm or more to obtain a stable yield during the manufacture of the product, it is possible to ensure excellent flex resistance. In addition, the anti-counterfeiting product for clothing can be sewn or bonded without damage.

In addition, the present invention may implement a hologram image and a background having a pure unique color by simply adding a color to the body 110. This is because the present invention does not pass through the metal thin film layer to form a hologram, so there is no problem that pure intrinsic colors are lost due to interference of the metal thin film layer. For reference, conventionally, a method for adding a color to a hologram image utilizes a method of forming a colored primary layer coated with a thermosetting lacquer having a color on the entire surface of the metal thin film layer. Could not implement

In addition, the present invention can simply implement the transparent or translucent product in the opaque product without going through a separate difficult process simply by providing the body 110 in the same context as transparent or translucent. As described above, the present invention can be easily implemented without choosing an opaque, transparent, or translucent product.

5 is a state diagram showing the state that the hologram panel according to the present invention is used as a forgery preventing product for clothing.

As shown, the hologram panel 100 according to the present invention can be suitably used as an anti-counterfeiting product for clothing that is subjected to severe bending and contact with water during washing, and is simply sewing on the outer side or the inner side of the garment 300. Or used in conjunction. Reference numeral 310, which is not referred to by reference, indicates the position where the hologram panel 100 of the present invention is to be located.

Subsequently, a mold for manufacturing the hologram panel 100 according to the present invention will be briefly described below.

6 is a longitudinal cross-sectional view for explaining a mold for manufacturing a hologram panel according to the present invention, Figure 7 is a plan view of a lower mold of the mold for manufacturing a hologram panel according to the present invention.

As shown, in order to manufacture the hologram panel of the present invention is provided with a master panel (220a) formed with a positive angle (220b) for forming the holographic image irregularities (111) and the first stage 210 and the second stage 220 The upper mold (210,220) consisting of the upper mold (210,220) is installed to correspond to, forming the mold in a position facing the positive intaglio (220b) of the master panel (220a) for molding the hologram panel (100) A lower mold 230 with 233 is required.

The upper mold 210 and 220 and the lower mold 230 are provided with an injection hole 211 and a distribution port 212,222,232 for injecting a liquid TPU, including an equalization chamber 221 for uniformly dispersing the liquid TPU. Chambers 221, 231, 233, 234 are provided.

In addition, when the liquid TPU is solidified and the hologram panel 100 is completed, a lifting pin 235 for lifting and separating it from the forming mold 233 is provided in the lower mold 230 to be able to lift and lower the liquid.

The molds 210, 220, and 230 for manufacturing the hologram panel 100 of the present invention will be further described with reference to a method for manufacturing the hologram panel.

Referring to the accompanying drawings, a method for manufacturing a hologram panel according to the present invention configured as described above is as follows.

First, the steps of preparing the upper molds 210 and 220 and the lower mold 230 for forming the hologram panel 100 are performed. To this end, the upper molds 210 and 220 having the master panel 221 formed on the lower surface of the positive relief 220b for the holographic image irregularities 111 are prepared. In addition, it is installed on the lower portion to correspond to the upper mold (210,220), in order to mold the hologram panel 100 is provided with a forming mold 233 in a position facing corresponding to the positive intaglio of the master panel 221 The lower mold 230 is prepared.

Thereafter, a step of injecting the liquid TPU (M) formed by applying high temperature to the mold 233 of the lower mold 230 is injected. To this end, in the state where the upper mold (210, 220) and the lower mold 230 is in contact with each other, the liquid TPU (M) is pressurized and injected through the injection hole 211 provided in the upper mold (210,220). Then, the liquid TPU (M) injected as shown in FIG. 8A flows stepwise through the chambers 221, 231, 233, 234 and the outlets 212, 222, 232 communicating with the upper molds 210, 220 and the lower mold 230, and finally, FIGS. As a result, the mold 233 is filled. This process is explained in more detail as follows.

That is, when the injection of the liquid TPU (M) by pressing the injection hole 211 of the upper mold (210,220) as shown in Figure 8a, the injected liquid TPU (M) is the upper mold (2) through the first distribution hole (212) The equalization chamber 221 located between the first stage 210 and the second stage 220 is gradually filled.

Thereafter, the equalization chamber 221 is filled, the liquid TPU (M) is moved through the second distribution port 222 to the middle located between the second stage 220 and the lower mold (210,220) and the lower mold (230). The chamber 231 is filled.

Subsequently, as the intermediate chamber is filled as shown in FIG. 8B, the liquid TPU M gradually fills the mold 233 and the auxiliary mold 234 through the third flow port 232.

If the liquid TPU (M) completely fills the mold 233 by pressing, the liquid TPU (M) is formed by the positive indent 220b of the master panel 221 located on the mold 233. ), Hologram image irregularities 111 for implementing the hologram image 120 are formed.

Thereafter, the step of cooling and solidifying the liquid TPU (M) filled in the mold 233 and the auxiliary mold 234 is performed. As a result, the liquid phase TPU M is solidified and the molding of the hologram panel 100 is completed.

After the solidification of the liquid TPU M is completed, the upper molds 210 and 220 are lifted from the lower mold 230 as shown in FIG. 8C.

Thereafter, as shown in FIG. 8D, the hologram panel 100 formed by solidifying the liquid TPU M is separated from the mold 233. To this end, when the lifting pin 235 installed to be lifted on the lower mold 230 is raised, the hologram panel 100 is easily separated from the mold 233.

As shown in FIG. 9, the hologram panel 100 separated from the mold 233 is in a state in which a plurality of hologram panels 100 are connected by the frame 131, and the stool 132 according to injection molding remains.

As described above, according to the manufacturing method of the present invention, since the product having the holographic image irregularities is simply implemented by the holographic image irregularities 111 formed directly on the front surface of the single body 110 made of TPU, the metal thin film layer by vacuum deposition is formed. There is no need for additional processing or post-processing, such as forming.

Although the method for manufacturing the hologram panel of the present invention by injection molding has been described above, the hologram panel of the present invention is easy to be manufactured not only by injection molding but also by press molding because it is formed of a body having a single layer. In this case, pressing may be performed by directly utilizing a solid TPU material instead of a liquid TPU.

Although preferred embodiments of the present invention have been described above, the present invention may use various changes, modifications, and equivalents. It is clear that the present invention can be applied in the same manner by appropriately modifying the above embodiments. Accordingly, the above description does not limit the scope of the invention as defined by the limitations of the following claims.

110: body 111: hologram image irregularities
120: hologram image 131: connection frame
210,220: upper mold 211: injection hole
212: first distribution port 220a: master panel
220b: positive intaglio 221: uniform chamber
222: second distribution port 230: lower mold
231: intermediate chamber 232: third distribution port
233: molding mold 234: auxiliary molding mold
235 lifting pin

Claims (12)

Holographic image irregularities are directly formed on the front surface of the body of TPU (Thermoplastic Polyurethane) material having wear resistance and flex resistance, so that the holographic image irregularities can be directly seen from the front without passing through another layer.
The manufacturing method includes the steps of: providing an upper mold having a master panel having an embossed surface for forming holographic image irregularities; Providing a lower mold provided to correspond to the upper mold, the lower mold having a forming mold at a position facing the positive and negative of the master panel to mold the hologram panel; Pressurizing and injecting a liquid material for forming a hologram panel in a state where the upper mold and the lower mold are in contact with each other by pressing the mold of the lower mold; When the filling of the material to the mold is completed, the step of cooling the material filled in the mold to solidify,
In order to press and inject the liquid material into the mold of the lower mold, a plurality of molds are formed in the lower mold, the upper mold is formed in multiple stages in one stage and two stages in the upper, An equalization chamber may be provided between the first and second stages of the upper mold to fill the liquid material firstly through the first distribution port, and a second distribution of the liquid material filling the equalization chamber may be provided between the second and second upper molds. An intermediate chamber is provided to move through the sphere to fill the secondary, and a third distribution port for moving the liquid material filling the intermediate chamber to the plurality of forming molds is provided, and the equalization chamber is formed of the liquid material. And after filling the intermediate chamber in sequence so as to finally fill the plurality of molding dies. delete The method of claim 1,
The body is a hologram panel, characterized in that consisting of only one layer in which the holographic image irregularities are formed. delete The method of claim 1,
The body panel is characterized in that the color is added. The method of claim 1,
Hologram panel, characterized in that the body is transparent or translucent. The method of claim 1,
The hologram panel is a hologram panel, characterized in that for clothing used to be attached to the garment. The method of claim 1,
And the body has a thickness of at least 1.5 mm or more. As a method of manufacturing a hologram panel,
Providing an upper mold having a master panel having an embossed surface for forming hologram irregularities;
Providing a lower mold provided to correspond to the upper mold, the lower mold having a forming mold at a position facing the positive and negative of the master panel to mold the hologram panel;
Pressurizing and injecting a liquid material for forming a hologram panel in a state where the upper mold and the lower mold are in contact with each other by pressing the mold of the lower mold;
When the filling of the material to the mold is completed, the step of cooling the material filled in the mold to solidify,
In order to press and inject the liquid material into the mold of the lower mold, a plurality of molds are formed in the lower mold, the upper mold is formed in multiple stages in one stage and two stages in the upper, An equalization chamber may be provided between the first and second stages of the upper mold to fill the liquid material firstly through the first distribution port, and a second distribution of the liquid material filling the equalization chamber may be provided between the second and second upper molds. An intermediate chamber is provided to move through the sphere to fill the secondary, and a third distribution port for moving the liquid material filling the intermediate chamber to the plurality of forming molds is provided, and the equalization chamber is formed of the liquid material. After filling the intermediate chamber in sequence, and to finally fill the plurality of forming molds,
The liquid material is a method of manufacturing a holographic panel, characterized in that the use of TPU (Thermoplastic Polyurethane) so that the finished product has flex resistance and wear resistance. 10. The method of claim 9,
And after the solidifying step is completed, lifting a lifting pin in the lower mold to separate the solidified hologram panel from the mold. delete delete

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