KR102057000B1 - Structure layered by soft layer having semi-melted grain - Google Patents

Abstract

The present invention relates to a soft flexible laminate structure in the form of semi-melted grain. The soft flexible laminate structure includes a caring layer that is arbitrarily set in a preset virtual boundary line and forms the base of a laminated structure; and a soft layer which is formed of a plurality of semi-melted grains, is sputtered in a preset virtual boundary line on the carrying layer, is temporarily seated in a preset boundary line on the carrying layer through the mutual adhesion of the plurality of fine particles, and can be arbitrarily removed along a boundary line preset by a user. It is possible to form various thickness.

Description

Structural layered by soft layer having semi-melted grain

TECHNICAL FIELD The present invention relates to a structure in which soft soft lamination is performed, and more particularly, to a label paper having a soft soft layer which is mutually bonded in the form of partially melted fine particles to control the spacing between these particles and has a layer structure. Field.

As the margin of digital label printing is increasing compared to the traditional printing method, the number of cases of label printing through a single-digit digital label printing machine is increasing in the label printing method, which was performed by flexo printing or offset printing.

In addition, the work using matte or semi-gloss papers that anyone can do is not easy to differentiate, and competition is fierce, and the margin of the printing market in each field using unique and special materials is relatively high.

In line with this trend, printing companies in major developed countries such as Japan, the United States, and the EU are promoting sustainable growth by promoting convergence and business diversification management with other industries beyond the existing market range of the printing culture industry. Fusion printing technology is being developed. Among them, a technology related to a fancy business or building materials using a messenger emoticon is being developed. Representative prior patent documents are "Adhesive sheet for construction and its manufacturing method (Registration No. 10-1484660, hereinafter Patent Document 1). ") Exists.

In the case of Patent Literature 1, the adhesive sheet for construction and a method for producing the same, release paper treated with silicon; An edge having a predetermined height by being line-printed along the periphery of the shape portion on the upper surface of the release paper; Disclosed is a pressure-sensitive adhesive sheet for building, characterized in that the screen is printed on the upper surface of the release paper inside, including a shape formed to have a texture.

Similarly, "adhesive interior material using digital printing technology and its manufacturing method (registration number 10-0948628, hereafter referred to as patent document 2)" also exist.

In the case of Patent Literature 2, the interior layer is formed with a base layer, a printed layer positioned above the base layer and printed with letters and patterns, and a pressure-sensitive adhesive layer disposed below the base layer and treated with a pressure-sensitive adhesive on the bottom thereof. The printing layer is formed by digital printing by an indirect printing method or a direct printing method, and the adhesive layer relates to an interior material using a digital printing technology formed by forming a silicone coating layer on a release paper made of paper and coating an adhesive on the surface thereof. . In addition, the present invention comprises the steps of: a) producing a PVC sheet using a PVC calendar; b) plywood the PVC sheet and the PET film; c) treating the adhesive on the release paper; d) bonding the release paper to the surface of the PET film; And e) after the digital photorealistic printing on the transfer paper coated with an acrylic film, and the transfer printing on the PVC sheet, the method of manufacturing an interior material using a digital technology characterized in that it comprises a.

There is also a "method of manufacturing interior materials using transfer paper and interior materials using the method (registration number 10-0791774, hereinafter referred to as Patent Document 3)."

In the case of Patent Document 3, the present invention relates to a method of manufacturing interior materials using a transfer paper, which includes, in particular, a release paper processing step of coating a silicone release agent on a surface of a release paper; An acrylic resin layer coating step of coating the acrylic resin layer on the surface of the release paper manufactured by the release paper processing step to improve the printability of the surface of the release paper to facilitate digital printing printing; An image printing step of manufacturing a transfer paper by printing an image with a digital inkjet printer on a variety of designs of photographs, pictures, and patterns desired by a consumer on the acrylic resin layer of the release paper formed by the resin layer coating step; A base paper bonding step of bonding the image of the transfer paper manufactured through the image printing step with the base paper to be transferred; And a post-treatment processing step of bonding a label layer or a surface reinforcement layer to the surface of the transfer paper to enhance the durability of the transfer paper after the transfer of the transfer paper image is transferred to the base paper by the base bonding step. The technical idea of the interior manufacturing method using a transfer paper is disclosed.

In addition, "interior decorative sheet and its manufacturing method (Publication No. 10-2008-0024351, hereinafter referred to as Patent Document 4) also exist.

In the case of Patent Document 4, a transfer film and a method of manufacturing the transparent printing layer, a metal deposition layer, and an adhesive layer, which are sequentially stacked on the PET carrier film, and an adhesive layer, a metal deposition layer, and a transparent layer on a colored PVC film as a base layer Disclosed are a technical sheet related to a decorative sheet on which a transparent PVC film as a printing layer and a surface layer are laminated, and a method of manufacturing the same.

Lastly, there is also "a mural tile using a digital printer and an epoxy and a manufacturing method thereof (published number 10-2010-0110200, hereinafter referred to as Patent Document 5)."

Patent Literature 5 relates to a mural tile using a digital printer and epoxy and a method of manufacturing the same. It is to provide a mural tile using a digital printer and epoxy and a method of manufacturing the same.

The invention according to Patent Document 5 for achieving the above object is to prepare a base plate material and acutely cut at 1 degree or more, 45 degrees or less like a tile in the size of adjustment to form a space like a tile naturally, the base plate prepared as described above Break away from the direct printing method on the material, and print the picture on the material such as paper, fabric, PVC paper which is most suitable for dye or pigment ink, and attach the image sheet to the base plate with adhesive glue, and pour epoxy on it to form convex film. After molding the epoxy layer and then undergoing the first natural drying process, after drying for 12 hours or more in an artificial dryer in the second, characterized in that the UV coating.

1 is a side view illustrating a phenomenon that appears when the molten epoxy is injected onto the fabric. 2 is a side view illustrating a state in which molten epoxy is trapped in a partition wall and then molten epoxy is injected through a conventional method. 3 is a photograph of a conventional fancy product showing that the epoxy is torn off the fabric when the fabric is bent. Figure 4 is a side view showing a phenomenon that the epoxy is torn off the fabric when the fabric is bent.

Conventionally, when an epoxy layer is placed on a label and then the label is bent at an angle, the boundary of the epoxy layer is separated from the label.

In the past, there was a problem that various patterns of epoxy could not be formed on the label. To form such a pattern, the label was placed on a plane, and then the actual boundary forming the various patterns was formed. When the fully molten epoxy is injected to have a very low viscosity, the waste of time due to the cooling of the epoxy is large and thus the production efficiency is greatly reduced.

As described above, since the fully molten epoxy has to be injected into the actual boundary and cooled, a problem of deterioration due to the generation of bubbles may occur in this process, and thus a separate process of removing the bubbles may be performed. There was also a problem.

Conventionally, due to the structural problem of the label between the rollers and the method of injecting the molten epoxy liquid as described above, there was also a structural problem that only the height of the epoxy layer can be formed uniformly.

Registration No. 10-1484660 Registration No. 10-0948628 Registration No. 10-0791774 Publication No. 10-2008-0024351 Publication No. 10-2010-0110200

The soft soft laminated structure in the form of the partially molten particulate according to the present invention has been devised to solve the above-described problems, and presents the following problems to be solved.

First, it is possible to build a soft flexible structure that can form a variety of thicknesses, not a constant thickness.

Secondly, it enables a firm attachment so that unintended stripping does not occur on the label or film.

Third, it is intended to facilitate the intended removal on the label or film.

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

The soft soft laminated structure in the form of a partially molten particulate according to the present invention has the following problem solving means for the above problem to be solved.

The soft soft laminated structure in the form of a partially molten particulate according to the present invention comprises: a carrying layer having a predetermined virtual boundary line arbitrarily set and forming a base of the laminated structure; And a plurality of partially melted fine particles, sputtered in the preset virtual boundary line on the carrying layer, and temporarily seated in the preset boundary line on the carrying layer through mutual adhesion of the plurality of fine particles, and It can be characterized in that it comprises a soft layer (soft layer) that can be removed arbitrarily along the predetermined boundary line by.

The soft layer of the soft flexible laminate structure in the form of a partially molten particulate according to the present invention further comprises a soft add layer in which an arbitrary monolayer is formed on the upper surface of the soft layer through arbitrary sputtering of the plurality of particulates. can do.

The soft flexible laminate structure in the form of a partially molten particulate according to the present invention may further include a base layer laminated on a lower surface of the soft layer and separating the soft layer and the carrying layer from each other.

In the soft soft laminated structure in the form of partially molten particulate according to the present invention, a plurality of arbitrary particles are sputtered on the upper surface of the base layer, and each of the plurality of arbitrary particles has a specific wavelength band of visible light irradiated from the top of the soft layer. It may be characterized in that it further comprises an absorption layer to selectively absorb.

The soft layer of the soft soft laminate structure in the form of a partially molten particulate according to the present invention may be characterized in that it is temporarily fixed to the carrying layer selectively selectively only to the predetermined virtual boundary line.

The carrying layer of the soft flexible laminate structure in the form of partially molten particulate according to the present invention may be characterized by forming a plurality of pores of micrometer diameter in the upper surface.

In the carrying layer of the soft flexible laminate structure in the form of a partially molten particulate according to the present invention, when the stretching occurs in the longitudinal direction, the diameter of the plurality of pores also occurs in the longitudinal direction, the carrying layer is in the longitudinal direction When the length is increased by a predetermined length, the diameters of the plurality of pores in the length direction may be extended by the predetermined length.

The base layer and the ablation layer of the soft flexible laminate structure in the form of a partially molten particulate according to the present invention may be characterized in that a temporary downward settlement occurs on top of the expanded plurality of pores.

The fine particles of the soft layer of the soft soft laminate structure in the form of partially melted fine particles according to the present invention may be characterized in that the impregnation occurs in the region where the temporary downward settlement occurs.

When the soft layer of the soft soft laminate structure in the form of partially molten particulate according to the present invention is stretched by the predetermined length in the longitudinal direction of the carrying layer, and then contracted by the predetermined length, the horizontal structure of the fine particles is It may be characterized by being compact.

The soft flexible laminate structure of the partially molten particulate form according to the present invention having the above configuration provides the following effects.

First, the soft, soft structure in the form of particulates is prevented from random stripping on the label, and the intended stripping is facilitated.

Second, to provide a soft flexible laminate structure having various thicknesses rather than a consistent thickness.

Thirdly, solid adsorption is made from the printing surface to prevent random stripping of the printed layer on the lower surface.

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

1 is a side view illustrating a phenomenon that appears when the molten epoxy is injected onto the fabric.
2 is a side view illustrating a state in which molten epoxy is trapped in a partition wall and then molten epoxy is injected through a conventional method.
3 is a photograph of a conventional fancy product showing that the epoxy is torn off the fabric when the fabric is bent.
Figure 4 is a side view showing a phenomenon that the epoxy is torn off the fabric when the fabric is bent.
FIG. 5 is a side view illustrating a process of fabricating a soft flexible laminate structure in the form of partially molten particulate according to an embodiment of the present invention.
FIG. 6 is a plan view showing preset virtual boundary lines for forming a soft flexible laminate structure in the form of a partially molten particulate according to an embodiment of the present invention.
FIG. 7 is a plan view illustrating a soft layer formed on some of the preset virtual boundary lines illustrated in FIG. 6.
FIG. 8 is a side view of a soft flexible laminate structure formed in the form of partially melted fine particles according to an embodiment of the present invention, and a partially enlarged view illustrating fine particles of the soft layer.
9 is a side view of a soft flexible laminate structure in the form of partially molten particulate according to another embodiment of the present invention.
FIG. 10 is a plan view and a perspective view illustrating a predetermined stretching of a carrying layer when forming a soft flexible laminate structure in the form of a partially molten particulate according to an embodiment of the present invention.
FIG. 11 is a plan view illustrating an increase in a pore on an extrusion layer or a base layer on a carrying layer as the carrying layer increases in forming a soft flexible laminate structure in the form of a partially molten particulate according to an exemplary embodiment of the present invention. .
FIG. 12 illustrates fine particles constituting a soft layer in an aperture layer on a carrying layer or a pore on a base layer as the carrying layer increases when forming a soft soft laminated structure in the form of a partially molten particulate according to an embodiment of the present invention. Shows the impregnation.
FIG. 13 is a plan view showing that the soft fine particles constituting the soft layer of the soft flexible laminate structure in the form of partially melted fine particles according to an embodiment of the present invention are formed to have a dense structure horizontally.
FIG. 14 is a side view illustrating a preset virtual boundary line of a soft layer of a soft soft laminate structure in the form of partially molten particulate according to an embodiment of the present invention.
FIG. 15 is a side view illustrating the soft add layer and the soft edge layer on a preset virtual boundary line in B of FIG. 14.

Soft soft laminate structures in the form of partially molten particulate according to the present invention may have various modifications and may have various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all changes, equivalents, and substitutes included in the technical spirit and scope of the present invention.

FIG. 5 is a side view illustrating a process of fabricating a soft flexible laminate structure in the form of partially molten particulate according to an embodiment of the present invention. FIG. 6 is a plan view showing preset virtual boundary lines for forming a soft flexible laminate structure in the form of a partially molten particulate according to an embodiment of the present invention. FIG. 7 is a plan view illustrating a soft layer formed on some of the preset virtual boundary lines illustrated in FIG. 6. FIG. 8 is a side view of a soft flexible laminate structure formed in the form of partially melted fine particles according to an embodiment of the present invention, and a partially enlarged view illustrating fine particles of the soft layer. 9 is a side view of a soft flexible laminate structure in the form of partially molten particulate according to another embodiment of the present invention. FIG. 10 is a plan view and a perspective view illustrating a predetermined stretching of a carrying layer when forming a soft flexible laminate structure in the form of a partially molten particulate according to an embodiment of the present invention. FIG. 11 is a plan view illustrating an increase in a pore on an extrusion layer or a base layer on a carrying layer as the carrying layer increases in forming a soft molten laminate structure in the form of a partially molten particulate according to an exemplary embodiment of the present invention. . FIG. 12 illustrates fine particles constituting a soft layer in an aperture layer on a carrying layer or a pore on a base layer as the carrying layer increases when forming a soft soft laminated structure in the form of a partially molten particulate according to an embodiment of the present invention. Shows the impregnation. FIG. 13 is a plan view showing that the soft fine particles constituting the soft layer of the soft flexible laminate structure in the form of partially melted fine particles according to an embodiment of the present invention are formed to have a dense structure horizontally. FIG. 14 is a side view illustrating a preset virtual boundary line of a soft layer of a soft soft laminate structure in the form of partially molten particulate according to an embodiment of the present invention. FIG. 15 is a side view illustrating the soft add layer and the soft edge layer on a preset virtual boundary line in B of FIG. 14.

The soft flexible laminate structure in the form of partially molten particulate according to the present invention will include a carrying layer 200 and a soft layer 100, as shown in FIG.

First, in the case of the carrying layer 200, a virtual boundary line w 'that can be arbitrarily set in various ways may be set on the upper surface.

The carrying layer 200 is a material different from the material of the soft layer 100 to be seated thereon, and may be made of a transparent film, coated paper, a tube, or the like, which has a phenomenon of being stretched only to a very small extent by external tension. Can be.

Existing thread boundary line (w) is actually set on the fabric, such as a film, the problem of having to inject molten epoxy into the set boundary line (w) and form the partition wall 30 to form a constant thickness of such epoxy On the other hand, in the case of this arbitrary setting line w 'of the present invention, unlike the existing real boundary line w, it corresponds to a virtual boundary line which does not actually exist.

As shown in FIG. 5 so that the soft layer 100 exists only within this imaginary boundary line w ', those in the form of partially melted or semi-melted particulates are placed on the imaginary boundary line on the carrying layer 200. When sprinkled, as soon as they are sown, these particles bond to each other to form a uniform structure.

In the case of the preset virtual boundary line w ', as shown in FIG. 6, when viewed in plan view, various patterns may be formed to be virtually set, and a plurality of particles may be sputtered only in the virtual boundary line. It may be stacked to form a shape as shown in 7.

In the case of the soft layer 100, as described above, the soft layer 100 corresponds to an aggregate of a plurality of partially melted fine particles 101 and is stacked on the carrying layer 200.

In the case of the soft layer 100, as shown in FIG. 8, dozens or hundreds of layers of those in the form of particulates 101 may be formed by loading, which soft layer may be a predetermined virtual boundary as described above. It is selectively formed only in the line w '.

The soft layer 100 is temporarily seated on the above-described preset virtual boundary line w 'of the carrying layer 200 as described above, and the preset virtual boundary line w as described above by the user. It can be removed according to ').

In the case of the soft layer 100, as described above, the plurality of fine particles are sputtered in a partially molten state so that the layers are stacked, and a thickness extending from the lower surface to the upper surface may be uniformly formed, Optionally, an irregular surface may be formed on the upper surface thereof, and as illustrated in FIG. 15, a soft add layer 100-1 may be further formed on the upper surface to form another arbitrary monolayer. It may be.

As described above, the soft layer 100 as an aggregate of the fine particles 101 is laminated on the carrying layer 200, and more preferably, after the stacked up to the soft add layer 100-1, the carrying layer 200 is formed. When passing through a plurality of feed rollers or the like and curved in the direction of the top or bottom surface, the soft layer 100 may move smoothly between these feed rollers without causing an unintended stripping phenomenon on the carrying layer 200.

In the case of the soft layer 100 and the soft add layer 100-1, which may be formed of a plurality of layers, when the carrying layer 200 is transferred between the transfer rollers, Even when pressurized by the temporary contraction, it will be back to its thickness by the self-resilience of the fine particles (101).

As shown in FIG. 9, the soft flexible laminate structure in the form of a partially molten particulate according to the present invention may further include a base layer 400.

In the case of the base layer 400, the soft layer 100 may be removed from the carrying layer 200 while being stacked on the lower surface of the soft layer 100.

The base layer 400 may be a silver foil coating layer such as aluminum foil, and the base layer 400 and the soft layer 100 are bonded to each other, and the base layer 400 and the carrying layer 200 are heterogeneous to each other to be easily separated. It is preferable that it is a laminated structure.

More preferably, in the case of the soft soft laminated structure in the form of the partially molten particulate according to the present invention, it may further include an absorption layer 300. In this case, as shown in FIG. 9, the soft layer 100, the application layer 300, the base layer 400, and the carrying layer 200 may be stacked in this order.

In the case of FIG. 9, the soft layer 100, the extrusion layer 300, and the base layer 400 are bonded to each other, and the layer structure of the soft layer 100, the absorption layer 300, and the base layer 400 is Since it may be temporarily seated along a predetermined virtual boundary line w 'of the carrying layer 200, it may be arbitrarily removed.

In the preferred example of FIG. 9, the soft layer 100 and the collection of layers included in the lower layer may be temporarily fixedly attached to the carrying layer 200 along only a predetermined virtual boundary line.

As illustrated in FIG. 15, in the case of the soft soft laminated structure in the form of partially molten particulate according to the present invention, the soft edge layer 100-2 may further include a soft edge layer 100-2.

In the case of the soft edge layer 100-2, in the form of fine particles, the thickness h is a few micro units, and is an extended form of the soft layer 100, outside the preset virtual boundary line w ′. . Through the presence of such a soft edge layer 100-2, the soft layer 100 may be selectively seated only on its preset virtual boundary line w ′.

As shown in FIG. 15, the soft edge layer 100-2 may be formed with a wedge groove 100-2e. As described above, the above-described preset virtual boundary line on the carrying layer 200 may be formed. Along the w ', the soft layer 100 corresponds to a kind of cutting line formed to be easily removed.

More preferably, in the case of the soft soft laminated structure in the form of the partially molten particulate according to the present invention, the adhesive layer 500 may be further included.

In this case, the adhesive layer 500 may be formed on the lower surface of the soft layer 100, the application layer 300, and the base layer 400, and the carrying layer 200 may be formed on the lower surface of the adhesive layer 500. It is attached so as to adhere randomly.

As shown in Fig. 10, the carrying layer 200 is moved through two rollers arranged in parallel in the longitudinal direction, and these two rollers have a difference in rotation speed (w2-w1) to maintain their flatness. In this process, a constant elongation (L + a, see FIG. 11) of the carrying layer 200 is generated in this process, and when the two rollers are departed, the elongated length is restored to return to the original length L again. Process to come.

Since the soft layer 100 corresponds to the aggregate of the fine particles 101, the restoring force in the horizontal direction as well as the vertical restoring force acts on the soft layer 200 by stretching and contracting the carrying layer 200. Unintended partial stripping on the base layer 400 disposed on the soft layer 200 can be prevented and held in place.

Here, in the case of the soft soft laminated structure in the form of partially molten particulate according to the present invention, as shown in FIG. 11, a plurality of pores having a diameter of micrometers may be formed on the upper surface of the carrying layer 200. Can be.

When the carrying layer 200 extends in the longitudinal direction, the above-described plurality of pores may have their diameters extended in the longitudinal direction (see FIG. 11 (b)), and then the carry layer 200 may be When the longitudinal extension is released and restored, the pore diameter is also restored.

In this case, the base layer 400 and the ablation layer 300 having the structure as shown in FIG. 9 generate temporary downward settlement on the upper portion of the expanded plurality of pores, and in this case, the fine particles 101 of the soft layer 100 In this case, impregnation occurs in an area where temporary downward settlement occurs as shown in FIG. 12, so that the fine particles 101 are firmly attached to the adhesion layer 300 and the base layer 400.

As shown in FIG. 13, when restoration of the length occurs in accordance with the stretching of the length of the carrying layer 200, as described above, the restoration of the length of the base layer 400 and the absorption layer 300 is also performed. In this process, the compactness of the horizontal structure of the fine particles existing thereon is caused.

The scope of the present invention is determined by the matters set forth in the claims, and the parentheses used in the claims are not for the purpose of selective limitation, but are used for the definite elements, and the description in the parentheses is also to be interpreted as an essential element. Should be.

W: room boundary line W ': preset virtual boundary line
1: first roller 2: second roller
3: sputtering nozzle 10: fabric
20 molten epoxy 30 partition wall
100: soft layer
100-1: soft add layer
100-2: soft edge layer
101: (soft) fine particles
200: carrying layer 300: printing layer
400: base layer 500: adhesive layer

Claims (12)

delete delete delete delete delete delete delete delete A carrying layer for arbitrarily setting a predetermined virtual boundary line and forming a base of the laminated structure;
Formed of a plurality of partially melted fine particles, sputtered in the preset virtual boundary line on the carrying layer, and temporarily seated in the preset boundary line on the carrying layer through mutual adhesion of the plurality of fine particles, A soft layer that can be arbitrarily removed along the preset boundary line by;
A base layer stacked on a bottom surface of the soft layer to separate the soft layer and the carrying layer from each other; And
A plurality of arbitrary particles are sputtered on the upper surface of the base layer, each of the plurality of arbitrary particles includes an absorption layer that selectively absorbs a specific wavelength band of visible light irradiated from the top of the soft layer,
The carrying layer is
Form a plurality of pores of micrometer diameter in the upper surface,
The base layer is,
When the base layer is extended in the longitudinal direction by a predetermined length, the diameters of the plurality of pores also extend in the longitudinal direction by the predetermined length,
The Absence Layer is
A temporary downward settlement occurs on top of the expanded plurality of pores,
The fine particles of the soft layer,
The soft flexible laminate structure, characterized in that the impregnation occurs in the region where the temporary downward settlement occurs.
A carrying layer for arbitrarily setting a predetermined virtual boundary line and forming a base of the laminated structure;
Formed of a plurality of partially melted fine particles, sputtered in the preset virtual boundary line on the carrying layer, and temporarily seated in the preset boundary line on the carrying layer through mutual adhesion of the plurality of fine particles, A soft layer that can be arbitrarily removed along the preset boundary line by;
A base layer stacked on a bottom surface of the soft layer to separate the soft layer and the carrying layer from each other; And
A plurality of arbitrary particles are sputtered on the upper surface of the base layer, each of the plurality of arbitrary particles includes an absorption layer that selectively absorbs a specific wavelength band of visible light irradiated from the top of the soft layer,
The carrying layer is
Form a plurality of pores of micrometer diameter in the upper surface,
The base layer is,
When the base layer is extended in the longitudinal direction by a predetermined length, the diameters of the plurality of pores also extend in the longitudinal direction by the predetermined length,
The soft layer,
And extending in the longitudinal direction of the base layer by the predetermined length, and then contracting by the predetermined length, whereby the horizontal structure of the fine particles becomes dense.
delete delete

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