KR102250432B1 - Shape memory adhesive structure using light and manufacturing method of the same - Google Patents

Abstract

The shape-memory adhesive structure according to the present invention is formed of a light-emitting material that emits light when electricity is supplied and a shape-memory polymer whose rigidity changes by light emitted from the light-emitting material. As a result, it is in a fluidized state close to jelly and the shape corresponding to the surface of the object to be bonded is deformed, so that it is in close contact with a rough or curved surface or a surface with irregularities, thereby maximizing adhesion. In addition, when the light disappears by blocking electricity after being in close contact with the object to be bonded, it is solidified again and cured in a state in close contact with the surface of the object to be bonded, so that the adhesive state is maintained firmly and the adhesive strength can be improved. In addition, if electricity is again applied to the shape memory adhesive structure bonded to the object to be bonded to be fluidized using light, the shape memory adhesive structure can be easily detached from the object to be bonded and restored to its original shape, so that it can be reused.

Description

Shape memory adhesive structure using light and manufacturing method of the same}

The present invention relates to a shape-memory adhesive structure using light and a method for manufacturing the same, and more particularly, it is fluidized by light of a specific wavelength and adheres to a rough surface, and when the light disappears, it is solidified in a close contact state to maximize adhesion. It relates to a shape-memory adhesive structure and a method of manufacturing the same using light.

In general, in the manufacturing field of TVs, smartphones, and smart pads, a substrate transfer device is required to bond and transfer substrates of various sizes. Technology is being developed. In this dry adhesive structure, a plurality of fine cilia is disposed on a base member, and has an adsorption force through a structure having an end protruding from the end of each cilia.

However, since the conventional dry adhesive structure can be bonded only when the surface of the object to be bonded is flat, there is a problem in that it is impossible to bond to various surface roughnesses or surface shapes.

Korean Patent Application Publication No. 10-2009-32719

An object of the present invention is to provide a shape-memory adhesive structure using light that can be easily bonded to a rough surface, and that can be recycled because the shape can be restored, and a manufacturing method thereof.

The shape memory adhesive structure using light according to the present invention includes a base panel and a plurality of microcilia protruding from one side of the base panel, and at least one of the base panel and the plurality of microcilia is electrically A light emitting material that emits light when is applied, and the plurality of fine cilia includes a shape memory polymer whose stiffness is changed by the light of the light emitting material, and when electricity is applied to the light emitting material, the light of the light emitting material is As a result, when the shape memory polymer is fluidized and transformed into a shape corresponding to the shape of the surface of the object to be bonded, and when the light from the light emitting material disappears due to blocking electricity from the light emitting material, the shape memory polymer is solidified ( Solidification) is cured and fixed in a state in close contact with the surface of the object to be bonded, and when electricity is applied to the light-emitting material again in the fixed state, it is fluidized again by the light of the light-emitting material and is detachable from the object to be bonded. Is restored.

The method of manufacturing a shape memory adhesive structure using light according to the present invention includes microcilia protruding in a column shape on a base panel, and when electricity is applied to the base panel, at least one of the base panel and the microcilia is The fine cilia are fluidized by the light emitted by the included luminous material to be transformed into a shape corresponding to the shape of the surface of the object to be bonded to be in close contact, and when the light disappears due to the electricity being blocked, the fine cilia are solidified. It is cured and fixed in a state in close contact with the surface of the object to be bonded, and when electricity is applied again in the fixed state, it is fluidized again by the light of the light-emitting material to be detachable from the object to be bonded and the shape is restored. A method of manufacturing a memory adhesive structure, the method comprising: applying a shape memory polymer to a mold on which a pattern of the base panel and the fine cilia is formed; Laminating an LED layer formed of the light-emitting material on the layer on which the shape memory polymer is applied; Coating and curing the shape memory polymer on the LED layer; And completing the shape-memory adhesive structure in which the LED layer emitting light by electricity is inserted into the base panel when separated from the mold, and the shape-memory polymer includes azobenzene, spiropyran ( Spiropyran).

A method of manufacturing a shape memory adhesive structure using light according to another aspect of the present invention includes micro-cilia protruding in a column shape on a base panel, and when electricity is applied to the base panel, one of the base panel and the micro-cilia The fine cilia are fluidized by the light emitted by the light-emitting particles included in at least one to be transformed into a shape corresponding to the shape of the surface of the object to be bonded and adhered closely, and when the light disappears due to the electricity being blocked, the fine cilia are solidified. (Solidification) is cured and fixed in a state in close contact with the surface of the object to be bonded, and when electricity is applied again in the fixed state, light is re-fluidized by the light of the light-emitting particles, so that it is detachable from the object to be bonded and its shape is restored. A method of manufacturing a shape memory adhesive structure using a method comprising: coating and curing a material obtained by mixing light-emitting particles, a conductive material, and a shape memory polymer on the base panel and the mold in which the pattern of the fine cilia is formed; And completing the shape-memory adhesive structure in which light-emitting particles emitted by electricity are embedded in the base panel and the microcilia when separated from the mold, and the light-emitting particles are electroluminescence (Electroluminescence). ) Particles, and the conductive material includes at least one of a carbon nanomaterial, a silver nanomaterial, and a conductive metal, and the shape memory polymer includes at least one of azobenzene and Spiropyran.

A method of manufacturing a shape memory adhesive structure using light according to another aspect of the present invention includes microcilia protruding in a column shape on a base panel, and when electricity is applied to the base panel, the base panel and the microcilia The fine cilia are fluidized by the light emitted by the light emitting particles included in at least one of them, transformed into a shape corresponding to the shape of the surface of the object to be bonded, and adhere to each other. It is solidified and cured and fixed in a state in close contact with the surface of the object to be bonded, and when electricity is applied again in the fixed state, the light-emitting particles are re-fluidized by the light emitted so that it can be detached from the object to be bonded and its shape is restored. A method of manufacturing a shape-memory adhesive structure using light, comprising the steps of: injecting the light-emitting particles into a mold on which a pattern of the base panel and the fine cilia is formed, and disposing the light-emitting particles on the intaglio pattern of the fine cilia; Coating and curing a material in which a conductive material and a shape memory polymer are mixed on the mold into which the light-emitting particles are introduced; When separated from the mold, the fine cilia are formed on the base panel, the base panel is formed of the conductive material and the shape memory polymer, and the fine cilia are the light emitting particles, the conductive material and the shape memory. Including the step of completing the shape memory adhesive structure formed of a polymer, the light emitting particles are electroluminescence particles, and the conductive material includes at least one of a carbon nanomaterial, a silver nanomaterial, and a conductive metal. And, the shape memory polymer includes at least one of azobenzene and spiropyran.

The shape-memory adhesive structure according to the present invention is formed of a light-emitting material that emits light when electricity is supplied and a shape-memory polymer whose rigidity changes by light emitted from the light-emitting material. As a result, the shape corresponding to the surface of the object to be bonded is deformed by being in a fluidized state close to the jelly, so there is an advantage in that adhesion can be maximized by being in close contact with a rough or curved surface or a surface with irregularities.

In addition, when the light disappears by blocking electricity after being in close contact with the object to be bonded, it is solidified again and cured in a state in close contact with the surface of the object to be bonded, so that the adhesive state is maintained firmly and the adhesive strength can be improved.

In addition, if electricity is again applied to the shape memory adhesive structure bonded to the object to be bonded to be fluidized using light, the shape memory adhesive structure can be easily detached from the object to be bonded and restored to its original shape, so that it can be reused.

In addition, since the manufacturing method is simple and adheres well to various adhesive objects, it can be applied to a wider variety of fields.

1 is a view showing a shape memory adhesive structure using light according to a first embodiment of the present invention.
FIG. 2 is a diagram schematically illustrating a method of using the shape memory adhesive structure shown in FIG. 1.
3 is a view showing a method of manufacturing a shape memory adhesive structure using light according to the first embodiment of the present invention.
4 is a view showing a shape memory adhesive structure using light according to a second embodiment of the present invention.
5 is a view showing a method of manufacturing a shape memory adhesive structure using light according to a second embodiment of the present invention.
6 is a view showing a shape memory adhesive structure using light according to a third embodiment of the present invention.
7 is a view showing a method of manufacturing a shape memory adhesive structure using light according to a third embodiment of the present invention.

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

1 is a view showing a shape memory adhesive structure using light according to a first embodiment of the present invention.

Referring to FIG. 1, the shape memory adhesive structure 10 using light according to the first embodiment of the present invention includes a light-emitting material that emits light when electricity is applied, and a shape-memory polymer that changes shape by light of the light-emitting material. Including, and being fluidized by the light emitted from the light-emitting material to be transformed into a shape corresponding to the shape of the surface of the object to be bonded 2 to be in close contact, and when the light disappears, it is solidified again and the object to be bonded ( It is hardened and fixed in close contact with the surface of 2).

The shape memory adhesive structure 10 is formed of a base panel 11 and a plurality of fine cilia 12.

At least one of the base panel 11 and the plurality of fine cilia 12 includes a light-emitting material that emits light when electricity is applied. In this embodiment, it will be described as an example that the light emitting material is included only in the base panel 11.

The base panel 11 includes a light emitting layer 11a formed of the light emitting material, a shape memory layer 11b stacked on one side of the light emitting layer and formed of a shape memory polymer, and stacked on the shape memory layer 11B. And a base layer 11c formed of the shape memory polymer.

The light emitting layer 11a will be described as an example as an LED layer. That is, the light-emitting material is an LED, and the light-emitting layer 11a may be formed in a film or sheet shape.

Power supply devices 15 for supplying electricity to the emission layer 11a are connected to both ends of the emission layer 11a.

The shape memory layer 11b is laminated only on the surface of the light emitting layer 11a facing the microcilia 12 and is formed of the shape memory polymer.

The shape memory polymer is a reversible material that can be restored after its stiffness is changed by light. In the present embodiment, the shape memory polymer will be described as an example as being a polymer containing at least one of azobenzene and spiropyran. The shape memory polymer may be liquefied when light in a wavelength of about 300 to 400 nm is applied, and solidified again when the light disappears.

The base layer 11c is a layer laminated on the shape memory layer 11b and formed of the shape memory polymer. However, the present invention is not limited thereto, and of course, the base layer 11c may be formed of a general polymer other than the shape memory polymer. In addition, the base layer 11c may be omitted.

The fine cilia 12 are formed of the shape memory polymer so that the rigidity is changed by the light emitted from the light emitting layer 11a. The fine cilia 12 and the shape memory layer 11b will be described as being formed of the same material, for example.

The fine cilia 12 have a columnar portion 12a protruding from the surface of the base panel 11 in a columnar shape, and are formed extending from the columnar portion 12a and have a larger cross-sectional area than the columnar portion 12a. It includes an expansion-formed adsorption part 12b.

The pillar portion 12a is formed in a cylindrical shape, and a plurality of the pillar portions 12a are disposed to be spaced apart from each other at a predetermined interval on the surface of the base panel 11.

The adsorption part 12b will be described as an example of being formed in a disk shape. However, the present invention is not limited thereto, and the shape of the adsorption part 12b may be formed in various shapes.

FIG. 2 is a diagram schematically illustrating a method of using the shape memory adhesive structure shown in FIG. 1.

2A, when the surface of the bonding object 2 is roughly formed, uneven or bent, the adsorption part 12b of the microcilia 12 is in close contact with the surface of the bonding object 2 It doesn't work.

When electricity is supplied to the emission layer 11a, the emission layer 11a emits light. The power may be applied for a preset set time.

When light is emitted from the light emitting layer 11a, the rigidity of the shape memory layer 11b and the fine cilia 12 is weakened by the light, resulting in a fluidized state close to jelly.

When the fine cilia 12 are fluidized, the surface of the adsorption unit 12b can be easily transformed into a shape corresponding to the surface shape of the bonding object 2 and can be in close contact with the surface of the bonding object 2 . When the fine cilia 12 are fluidized, the shape memory adhesive structure 10 may be brought into close contact by applying a predetermined force.

When the adsorption part 12b is in close contact with the surface of the adhesion object 2, electricity is cut off to the light emitting layer 11a.

When the supply of electricity to the light-emitting layer 11a is cut off, the light-emitting layer 11a no longer emits light.

When light disappears from the light emitting layer 11a, the shape memory layer 11b and the fine cilia 12 are solidified again.

When the fine cilia 12 are solidified, the adsorption part 12b is hardened and fixed in a state in close contact with the adhesion object 2. That is, since the adsorption part 12b is in close contact with the adhesive object 2 and cured in a state deformed to fit the surface shape of the adhesive object 2, it can be firmly fixed to the adhesive object 2 .

Therefore, even if the surface of the adhesion object 2 is not smooth or flat, the fine cilia 12 may be fluidized in a soft state using light to maximize adhesion.

In addition, referring to FIG. 2C, when the shape memory adhesive structure 10 is to be separated from the adhesive object 2, electricity is again supplied to the light emitting layer 11a.

When electricity is supplied to the emission layer 11a, light is emitted from the emission layer 11a.

The fine cilia 12 are again fluidized by the light emitted from the light emitting layer 11a.

When the adsorption part 12b is fluidized, the shape memory adhesive structure 10 can be easily detached by pulling the shape memory adhesive structure 10 in a direction to remove it from the adhesive object 2.

When the shape memory adhesive structure 10 is detached, the fine cilia 12 may be restored to their original shape according to the shape memory characteristics of the shape memory polymer.

After the shape of the fine cilia 12 is restored, if electricity is cut off again in the light emitting layer 11a, the shape memory layer 11b and the fine cilia 12 are solidified again to restore their shape. Can keep.

Therefore, the shape memory adhesive structure 10 can be reused.

Meanwhile, in the first embodiment, the light emitting layer 11a has been described as an example of inserting a previously manufactured LED layer. However, the present invention is not limited thereto, and electroluminescence particles are used as the light-emitting material, and the light-emitting layer 11a is a film or sheet prepared by mixing the light-emitting material, the conductive material, and the shape memory polymer. It is also possible to do it. In addition, the light-emitting layer 11a may be a layer formed by coating the electroluminescence particles and the conductive material on the layer on which the shape memory polymer is applied to the mold 4. Here, the conductive material may include at least one of a carbon nanomaterial, a silver nanomaterial, and a conductive metal.

3 is a view showing a method of manufacturing a shape memory adhesive structure using light according to the first embodiment of the present invention.

Referring to FIG. 3A, the shape memory polymer is poured into the mold 4 on which the pattern of the base panel 11 and the fine cilia 12 is formed, as much as a preset height. Here, the set height is set according to the height of the fine cilia 12 and the height of the shape memory layer 11b.

Before the shape memory polymer is cured, the light emitting layer 11a is laminated on the layer coated with the shape memory polymer. In this embodiment, since the light emitting layer 11a is described as being the LED layer, the LED layer is stacked on the shape memory polymer.

Referring to FIG. 3B, the shape memory polymer is poured again on the light emitting layer 11a to laminate the base layer 11c and then cured.

Referring to FIG. 3C, when the cured structure is separated from the mold 4, the shape memory adhesive structure 10 having the plurality of fine cilia 12 formed on the base panel 11 is formed.

The shape memory adhesive structure 10 manufactured as described above is formed in a structure in which the light emitting layer 11a is inserted between the shape memory layer 11b and the base layer 11c.

4 is a view showing a shape memory adhesive structure using light according to a second embodiment of the present invention.

4, in the shape memory adhesive structure 20 using light according to the second embodiment of the present invention, a base panel 21 and a plurality of fine cilia 22 are electroluminescent particles 26 ), the conductive material 27 and the shape memory polymer 28 are mixed and manufactured differently from the first embodiment, and other configurations and functions are similar, and thus the different points will be described in detail.

The electroluminescence particles 26 are particles that emit light when electricity is applied. The electroluminescence particles 26 will be described as examples of using zinc oxide.

The conductive material 27 includes at least one of a carbon nanomaterial, a silver nanomaterial, and a conductive metal.

The shape memory polymer 28 contains at least one of azobenzene and spiropyran.

A power supply device 25 for supplying electricity to the shape memory adhesive structure 20 is connected to the base panel 21.

5 is a view showing a method of manufacturing a shape memory adhesive structure using light according to a second embodiment of the present invention.

5A, after the electroluminescence particles 26, the conductive material 27, and the shape memory polymer 28 are mixed at a preset ratio, the base panel 21 and the fine particles are mixed. It is cured by applying it to the mold 4 in which the pattern of the cilia 22 is formed at a time.

Before the curing, an electric wire for supplying power to the shape memory adhesive structure 20 may be inserted.

In the shape memory adhesive structure 20 according to the present embodiment, since the conductive material 27 is evenly distributed throughout the interior, there is no restriction on the connection position of the power supply device 25.

In addition, since electricity is evenly passed through the entire interior of the shape memory adhesive structure 20, electricity is well passed through the electrical luminescence particles 26, so that the electrical luminescence particles 26 evenly light up. There is an advantage that can be released.

6 is a view showing a shape memory adhesive structure using light according to a third embodiment of the present invention.

6, in the shape memory adhesive structure 30 using light according to the third embodiment of the present invention, a base panel 31 and a plurality of fine cilia 32 are electroluminescent particles 36 ), a conductive material 37, and a shape memory polymer 38, but the electroluminescence particles 36 are provided only on the fine cilia 32, which is different from the second embodiment. The rest of the configuration and operation are similar, so it will be described in detail focusing on the different points.

The electroluminescence particles 36 are particles that emit light when electricity is applied. The electroluminescence particles 36 will be described as an example of using zinc oxide.

The conductive material 37 includes at least one of a carbon nanomaterial, a silver nanomaterial, and a conductive metal.

The shape memory polymer 38 includes at least one of azobenzene and spiropyran.

A power supply device 35 for supplying electricity to the shape memory adhesive structure 30 is connected to the base panel 31.

7 is a view showing a method of manufacturing a shape memory adhesive structure using light according to a third embodiment of the present invention.

Referring to FIG. 7A, the electroluminescence particles 36 are injected into the mold 4 on which the base panel 31 and the fine cilia 32 are patterned.

The electroluminescence particles 36 are located in a portion in which the pattern of the fine cilia 32 is engraved.

Referring to FIG. 7B, after mixing the shape memory polymer 38 and the conductive material 37 at a preset ratio, the electroluminescence particles 36 are applied to the mold 4 Cure.

Before the curing, an electric wire for supplying power to the shape memory adhesive structure 30 may be inserted.

Referring to FIG. 7C, when the shape memory polymer 38 is cured, it is separated from the mold 4.

Therefore, the base panel 31 is formed of the conductive material 37 and the shape memory polymer 38, and the fine cilia 31 are the electroluminescence particles 36, the conductive material ( 37) and the shape memory polymer 38 are mixed and formed.

In the shape memory adhesive structure 30 according to the present embodiment, since the conductive material 37 is evenly distributed throughout the interior, there is no restriction on the connection position of the power supply device 35.

In addition, since electricity is evenly passed through the entire interior of the shape memory adhesive structure 30, electricity is well communicated to the electroluminescence particles 36, so that the electroluminescence particles 36 light evenly. There is an advantage that can be released.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those of ordinary skill in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

10, 20, 30: shape memory adhesive structure
11, 21, 31: base panel 11a: light emitting layer
11b: shape memory layer 12,22,32: microcilia
12a, 22a, 32a: column part 12b, 22b, 32b: adsorption part
26,36: electroluminescence particles 27,37: conductive material

Claims (13)

Including a base panel and a plurality of fine cilia protruding from one side of the base panel,
The base panel,
A light-emitting layer formed of a light-emitting material that emits light when electricity is applied, a shape-memory layer formed of a shape-memory polymer that is laminated on one side of the light-emitting layer and whose rigidity is changed by the light of the light-emitting material, and a polymer that is laminated on the other side of the light-emitting layer. It includes a base layer formed of,
The plurality of fine cilia,
It includes a shape-memory polymer whose rigidity is changed by the light of the light-emitting material, and includes a pillar portion protruding from the surface of the base panel in a pillar shape, and an adsorption portion extending from the pillar portion and formed to be adsorbed to an object to be bonded,
Further comprising a power supply device connected to both ends of the light emitting layer to supply electricity to the light emitting layer,
When electricity is supplied to the light-emitting layer, the shape memory polymer is fluidized by the light of the light-emitting material, so that the surface of the adsorption unit is transformed into a shape corresponding to the surface shape of the object to be adhered and adhered thereto,
When electricity is blocked by the light-emitting material and the light of the light-emitting material disappears, the shape memory polymer is solidified, and the adsorption portion is cured and fixed in a state in close contact with the surface of the adhesive object,
In the fixed state, when electricity is applied to the light-emitting material again, it is fluidized again by the light of the light-emitting material, so that the adsorption unit is detachable from the bonding object and the shape is restored. delete delete The method according to claim 1,
The light emitting layer is a shape memory adhesive structure using light including an LED layer. The method according to claim 1,
The light-emitting material is electroluminescence particles,
The light emitting layer is a shape memory adhesive structure using light manufactured in a film shape by mixing the electroluminescence particles, a conductive material, and the shape memory polymer. delete A base panel, a plurality of fine cilia protruding from one side of the base panel, and a power supply device for supplying electricity to the base panel,
The base panel and the microcilia are manufactured by mixing a light-emitting material, a conductive material, and a shape memory polymer whose stiffness changes by light of the light-emitting material,
The plurality of fine cilia,
And a pillar portion protruding from the surface of the base panel in a pillar shape, and an adsorption portion extending from the pillar portion and formed to be adsorbed to an object to be bonded,
When electricity is supplied to the base panel, the shape memory polymer is fluidized by the light of the light-emitting material, so that the surface of the adsorption unit is deformed into a shape corresponding to the surface shape of the object to be bonded and adhered thereto,
When electricity is cut off to the base panel and light of the light emitting material disappears, the shape memory polymer is solidified, and the adsorption portion is cured and fixed in a state in close contact with the surface of the adhesive object,
In the fixed state, when electricity is applied to the base panel again, it is fluidized again by the light of the light-emitting material, so that the adsorption unit is detachable from the object to be bonded and the shape is restored. The method according to claim 1 or 7,
The light-emitting material is a shape-memory adhesive structure using light including electroluminescence particles. The method of claim 8,
The electroluminescence particle is a shape memory adhesive structure using light including zinc oxide particles. The method according to claim 1 or 7,
The shape memory polymer,
A shape memory adhesive structure using light, which is a polymer containing at least one of azobenzene and spiropyran. A light-emitting layer formed of a light-emitting material that emits light when electricity is applied, a shape-memory layer formed of a shape-memory polymer that is laminated on one side of the light-emitting layer and whose rigidity is changed by the light of the light-emitting material, and a polymer that is laminated on the other side of the light-emitting layer. A base panel comprising a base layer formed of,
Including fine cilia including a pillar portion protruding from the base panel in a pillar shape and an adsorption portion extending from the pillar portion and adsorbed to the adhesive object,
When electricity is applied to the light-emitting layer, the fine cilia are fluidized by the light emitted from the light-emitting material, so that the adsorption unit is deformed into a shape corresponding to the shape of the surface of the adhesion object and adheres to it. When it disappears, the fine cilia are solidified and the adsorption part is hardened and fixed in a state in close contact with the surface of the adhesive object, and when electricity is applied again in the fixed state, it is fluidized again by the light of the light-emitting material, In the method of manufacturing a shape-memory adhesive structure using light that is detachable from the adhesive object and whose shape is restored,
The shape memory layer of the base panel formed of the shape memory polymer by applying a shape memory polymer to the base panel and the mold on which the pattern of the fine cilia is formed to form the pillar portion and the adsorption portion formed of the shape memory polymer Forming a;
Forming the light-emitting layer by stacking an LED layer made of the light-emitting material on the shape memory layer;
Forming the base layer by coating and curing the shape memory polymer on the light emitting layer;
Separating from the mold, including the step of completing the shape-memory adhesive structure in which the LED layer emitting light is inserted into the interior of the base panel by electricity,
The shape memory polymer is a polymer containing at least one of azobenzene and spiropyran. A method of manufacturing a shape memory adhesive structure using light. A base panel, a column part protruding from the base panel in a column shape, and a plurality of fine cilia including an adsorption part extended from the column part and adsorbed to an object to be bonded,
When electricity is applied to the base panel, the microcilia are fluidized by light emitted from light emitting materials included in at least one of the base panel and the microcilia, so that the adsorption unit corresponds to the shape of the surface of the adherend. When the light disappears because the electricity is cut off, the fine cilia are solidified and the adsorption unit is cured and fixed in a state in close contact with the surface of the object to be bonded, and electricity is re-energized in the fixed state. In the method of manufacturing a shape-memory adhesive structure using light that is fluidized again by light of the light emitting materials when applied so that the adsorption unit is detachable from the object to be bonded and its shape is restored,
Coating and curing a material obtained by mixing light-emitting materials, a conductive material, and a shape memory polymer on the base panel and the mold on which the pattern of the fine cilia is formed;
Separating from the mold, including the step of completing the shape-memory adhesive structure in which light-emitting materials that emit light by electricity are embedded inside the base panel and the microcilia,
The light-emitting materials are electroluminescence particles,
The conductive material includes at least one of a carbon nanomaterial, a silver nanomaterial, and a conductive metal,
The shape memory polymer is a polymer containing at least one of azobenzene and spiropyran. A method of manufacturing a shape memory adhesive structure using light. A base panel, a column part protruding from the base panel in a column shape, and a plurality of fine cilia including an adsorption part extended from the column part and adsorbed to an object to be bonded,
When electricity is applied to the base panel, the microcilia are fluidized by light emitted from light emitting materials included in at least one of the base panel and the microcilia, so that the adsorption unit corresponds to the shape of the surface of the adherend. When the light disappears because the electricity is cut off, the fine cilia are solidified and the adsorption unit is cured and fixed in a state in close contact with the surface of the object to be bonded, and electricity is re-energized in the fixed state. In the method of manufacturing a shape-memory adhesive structure using light in which the light emitting materials are re-fluidized by the light emitted when applied so that the adsorption unit is detachable from the adhesive object and its shape is restored,
Injecting the light-emitting materials into the base panel and the mold in which the pattern of the fine cilia is formed, and disposing the light-emitting materials on the intaglio pattern of the fine cilia;
Coating and curing a material obtained by mixing a conductive material and a shape memory polymer on the mold into which the light-emitting materials are added;
When separated from the mold, the fine cilia are formed on the base panel, the base panel is formed of the conductive material and the shape memory polymer, and the fine cilia are the light emitting materials, the conductive material and the shape memory. Comprising the step of completing the shape memory adhesive structure formed of a polymer,
The light-emitting materials are electroluminescence particles,
The conductive material includes at least one of a carbon nanomaterial, a silver nanomaterial, and a conductive metal,
The shape memory polymer is a polymer containing at least one of azobenzene and spiropyran. A method of manufacturing a shape memory adhesive structure using light.

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