CN222672570U - Dynamic sign - Google Patents

Abstract

The utility model discloses a dynamic sign, including a product layer and a conductive layer located below the product layer, the product layer contacts the conductive layer, the two sides of the conductive layer are respectively bonded with a first interactive layer and a second interactive layer that cooperate with the conductive layer and are used to achieve a dynamic adjustment effect, the first interactive layer is located in a hollow hole of the product layer, and the thickness of the first interactive layer is the same as the depth of the hollow hole. The user of the utility model controls the state of the conductive layer being energized or not energized, so that the first interactive layer, the second interactive layer and the conductive layer cooperate with each other, and different contents or appearance effects are displayed in the hollow hole of the product layer, thereby enriching the user's visual experience; in addition, the upper surface of the first interactive layer is flush with the upper surface of the product layer, and the edge of the sign will not warp or fall off after wiping the surface of the product layer for many times.

Description

Dynamic sign

Technical Field

The utility model relates to a signboard, in particular to a dynamic signage.

Background

Most of the tags in the market at present are made of metal, AB glue or other materials, the appearance effect and the content of the tags are unchanged when the tags are attached to products, and the visual interaction effect is poor. In order to achieve different appearance effects, a label is usually replaced, so that the cost is easy to increase, most of the labels are directly adhered to the surface of a product and have small step thickness, however, in order to keep the cleanliness of the product, the surface of the product is usually wiped for multiple times, the edges of the labels are easy to warp after being wiped for multiple times, and even the labels fall off from the product, so that the information of a user identifying the product is affected.

There is thus a need for improvements and improvements in the art.

Disclosure of utility model

In view of the above-mentioned shortcomings of the prior art, the present utility model is directed to providing a dynamic signage to solve the problem of poor use effect of the signage in the prior art.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

The utility model provides a developments sign, includes the product layer and is located the conducting layer of product layer below, product layer and conducting layer face contact, and the both sides face on conducting layer bonds respectively has and cooperates with the conducting layer, and is used for realizing the first interaction layer and the second interaction layer of dynamic adjustment effect, and first interaction layer is located the fretwork downthehole of product layer, and the thickness and the degree of depth of fretwork downthehole of first interaction layer are the same.

The first interaction layer and the second interaction layer are transparent PET layers, PC layers or acrylic layers.

The conducting layer is transparent conductive film glass, and is connected with a conducting wire group for supplying power.

Two sides of the conductive layer are respectively adhered to the first interaction layer and the second interaction layer through OCA optical adhesive layers.

The thickness of the OCA optical adhesive layer is 100-175 μm.

And the first interaction layer and the second interaction layer are provided with a film covering area, and the film covering area on the first interaction layer and the film covering area on the second interaction layer are arranged in a staggered mode.

The silk-screen printing ink layer is arranged on the first interaction layer and the second interaction layer, and the silk-screen printing area of the silk-screen printing ink layer on the first interaction layer and the silk-screen printing area of the silk-screen printing ink layer on the second interaction layer are arranged in a staggered mode.

A lighting device is arranged below the second interaction layer.

Compared with the prior art, the dynamic label comprises a product layer and a conductive layer positioned below the product layer, wherein the product layer is in contact with the conductive layer, two side surfaces of the conductive layer are respectively adhered with a first interaction layer and a second interaction layer which are matched with the conductive layer and are used for realizing a dynamic adjusting effect, the first interaction layer is positioned in a hollowed-out hole of the product layer, and the thickness of the first interaction layer is the same as the depth of the hollowed-out hole. In addition, the upper surface of the first interaction layer is level with the upper surface of the product layer, and the edge of the label does not generate the phenomenon of warping or falling after wiping the surface of the product layer for a plurality of times.

Drawings

Fig. 1 is a schematic structural diagram of a dynamic signage provided by the present utility model.

Description of the reference numerals

The product layer 1, the hollow hole 11, the conductive layer 2, the conductive wire group 21, the first interaction layer 3 and the second interaction layer 4.

Detailed Description

In order to make the objects, technical solutions and effects of the present utility model clearer and more specific, the present utility model will be described in further detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

It is noted that when an element is referred to as being "mounted," "secured," or "disposed" on another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or intervening elements may also be present.

It should be noted that, in the embodiments of the present utility model, terms such as left, right, up, and down are merely relative concepts or references to normal use states of the product, and should not be construed as limiting.

The utility model provides a dynamic label, referring to fig. 1, comprising a product layer 1 and a conductive layer 2 positioned below the product layer 1, wherein the product layer 1 is in surface contact with the conductive layer 2, two opposite side surfaces of the conductive layer 2 are respectively bonded with a first interaction layer 3 and a second interaction layer 4 which are matched with the conductive layer 2 and are used for realizing a dynamic adjustment effect, the first interaction layer 3 is positioned in a hollowed-out hole 11 of the product layer 1, and the thickness of the first interaction layer 3 is the same as the depth of the hollowed-out hole 11.

In the utility model, the upper and lower side surfaces of the conductive layer 2 are respectively adhered with the first interaction layer 3 and the second interaction layer 4 to form a label main body, the first interaction layer 3 is positioned in the hollowed-out hole 11 of the product layer 1, the peripheral side of the first interaction layer 3 is contacted with the inner wall surface of the hollowed-out hole 11, the upper surface of the first interaction layer 3 is flush with the upper surface of the product layer 1, the lower surface of the first interaction layer 3 is flush with the lower surface of the product layer 1, and the lower surface of the product layer 1 is contacted with the conductive layer 2 to limit the label main body on a product. It should be noted that, the product layer 1 is a part or a component of a product itself to which the dynamic signage is applied in the present utility model, the signage main body is installed from the inside of the product and is matched with the product layer 1, so that the first interaction layer 3 is placed in the hollowed-out hole 11 of the product layer 1, and the product layer 1 is in surface contact with the conductive layer 2, and meanwhile, a containing portion for containing the second interaction layer 4 is also provided on the product to ensure the stability of the installation of the dynamic signage, and the dynamic signage refers to that the signage can generate a change in content or appearance effect. In addition, the upper surface of the first interaction layer 3 is level with the upper surface of the product layer 1, and the edge of the label does not generate the phenomenon of warping or falling after wiping the surface of the product layer 1 for many times.

Further, the first interaction layer 3 and the second interaction layer 4 are transparent PET layers, PC layers or acrylic layers. In the application, the first interaction layer 3 and the second interaction layer 4 are transparent layers made of PET (polyethylene terephthalate, commonly called polyester resin), PC (polycarbonate) or acrylic materials, on one hand, when the conducting layer 2 is not electrified, the fog effect of the conducting layer 2 can be displayed through the first interaction layer 3, on the other hand, when the conducting layer 2 is electrified, the subsequent film coating, silk screen pattern or text and other contents are conveniently carried out on the first interaction layer 3 and the second interaction layer 4, and the first interaction layer 3, the conducting layer 2 and the second interaction layer 4 are matched to realize the content or appearance display.

Further, the conductive layer 2 is transparent conductive thin film glass, and the conductive layer 2 is connected with a conductive wire group 21 for supplying power. The conductive wire group 21 is connected with an external or internal power supply of a product, whether the conductive layer 2 is electrified or not can be controlled through a switch, transparent conductive glass has an opaque matte effect under the condition of no electrification, the label displays the overlapped content of the first interaction layer 3 and the conductive layer 2, transparent conductive glass has transparency under the condition of electrification, the label displays the overlapped content of the first interaction layer 3 and the second interaction layer 4, and the change of the label content display is realized by controlling whether the conductive layer 2 is electrified or not, so that a better decorative effect is achieved, and the cost of changing the label due to displaying different contents is reduced to a certain extent.

Further, both sides of the conductive layer 2 are respectively bonded to the first interaction layer 3 and the second interaction layer 4 through OCA optical adhesive layers. The OCA optical adhesive has the characteristics of high cleanliness, high light transmittance, low haze, high adhesive force, uniform thickness, high flatness and the like, the conductive layer 2 is adhered to the first interaction layer 3 and the second interaction layer 4 through the OCA optical adhesive layer, the adhesive strength between the first interaction layer 3, the second interaction layer 4 and the conductive layer 2 is improved, the thickness of an adhesive area is ensured to be uniform, the loss in light transmission is reduced, in addition, the OCA optical adhesive has good water resistance and defoaming effect, the problem that after a user wipes a dynamic label by dipping water for many times, the adhesive layer is affected by water infiltration in the dynamic label, and bubbles are generated is avoided, and the stability of the display effect of the dynamic label is ensured. The thickness of the OCA optical adhesive layer is 100-175 μm. Specifically, the thickness of the OCA optical adhesive layer can be 100 μm, 150 μm or 175 μm, and by controlling the bonding thickness of the OCA optical adhesive layer, on one hand, the cost can be reduced, and meanwhile, the too thick adhesive layer is prevented from affecting the light penetration effect, and on the other hand, the phenomenon that the bonding strength is insufficient and the bonding is uneven to generate bubbles or gaps due to the thinner adhesive layer is avoided.

Further, the first interaction layer 3 and the second interaction layer 4 are provided with film covering areas, and the film covering areas on the first interaction layer 3 and the film covering areas on the second interaction layer 4 are arranged in a staggered mode. The silk-screen printing ink layers are arranged on the first interaction layer 3 and the second interaction layer 4, and the silk-screen printing areas of the silk-screen printing ink layers on the first interaction layer 3 and the silk-screen printing areas of the silk-screen printing ink layers on the second interaction layer 4 are arranged in a staggered mode. According to the application, the contents such as patterns, characters and the like are increased by adopting a film coating or silk-screen printing mode on the first interaction layer 3 and the second interaction layer 4, the contents such as the patterns, the characters and the like on the first interaction layer 3 and the second interaction layer 4 are arranged in a staggered mode, when the conductive layer 2 is electrified, the conductive layer 2 presents a transparent effect, at the moment, the sign presents the contents formed by the first interaction layer 3 and the second transparent layer in a matched mode, when the conductive layer 2 is not electrified, the conductive layer 2 presents an opaque matte effect, and at the moment, the dial presents the contents formed by the first interaction layer 3 and the conductive layer 2 in a matched mode. In the present application, the film-coated areas and the screen ink layer areas on the first and second interaction layers 3 and 4 may be set according to actual needs, and the color, pattern, text, transparency, and the like thereof are not limited.

Further, a lighting device (not shown in the figure) is provided below the second interaction layer 4. The lighting device can adopt pure color or multi-color LED lamp strips to only play a lighting effect, the lighting device can also adopt patterns and characters formed by the pure color or multi-color LED lamp strips or the combination of the patterns and the characters, the lamp strips can be directly adhered below the second interaction layer 4, a space for accommodating the lamp strips is reserved in a product, when the conductive layer 2 is not electrified, the lighting device is turned on, the lighting effect formed by single or combined colors, patterns, characters and the like can be hidden through the sign main body, and when the conductive layer 2 is electrified, the lighting device is matched with the patterns on the first interaction layer 3 and the second interaction layer 4 to form other display effects, so that the content displayed by the sign is richer, and further the richer appearance effect is displayed.

In summary, the dynamic label provided by the utility model comprises a product layer and a conductive layer below the product layer, wherein the product layer is in contact with the conductive layer, two side surfaces of the conductive layer are respectively adhered with a first interaction layer and a second interaction layer which are matched with the conductive layer and are used for realizing a dynamic adjustment effect, the first interaction layer is positioned in a hollowed-out hole of the product layer, and the thickness of the first interaction layer is the same as the depth of the hollowed-out hole. In addition, the upper surface of the first interaction layer is level with the upper surface of the product layer, and the edge of the label does not generate the phenomenon of warping or falling after wiping the surface of the product layer for a plurality of times.

It will be understood that equivalents and modifications will occur to those skilled in the art in light of the present utility model and their spirit, and all such modifications and substitutions are intended to be included within the scope of the present utility model as defined in the following claims.

Claims (8)

1. The utility model provides a dynamic sign, its characterized in that, includes the product layer and is located the conducting layer of product layer below, the product layer with the conducting layer face contact, the both sides face on conducting layer bond respectively with the conducting layer cooperation, and be used for realizing the first interaction layer and the second interaction layer of dynamic adjustment effect, first interaction layer is located in the fretwork hole of product layer, just the thickness on first interaction layer with the degree of depth in fretwork hole is the same.

2. The dynamic signage of claim 1, wherein the first and second interactive layers are transparent PET layers, PC layers, or acrylic layers.

3. The dynamic signage of claim 2, wherein the conductive layer is transparent conductive thin film glass and a set of conductive wires for supplying power are connected to the conductive layer.

4. The dynamic signage of claim 3, wherein two sides of the conductive layer are bonded to the first and second interactive layers, respectively, by an OCA optical adhesive layer.

5. The dynamic signage of claim 4, wherein the OCA optical adhesive layer has a thickness of 100 μιη to 175 μιη.

6. The dynamic signage of claim 5, wherein the first and second interactive layers are provided with a laminating area thereon, the laminating area on the first interactive layer and the laminating area on the second interactive layer being offset.

7. The dynamic signage of claim 5, wherein the first and second interaction layers are provided with a screen printing ink layer, and a screen printing area of the screen printing ink layer on the first interaction layer is offset from a screen printing area of the screen printing ink layer on the second interaction layer.

8. The dynamic signage of claim 1, wherein a light is provided below the second interactive layer.