Patent Description:
<CIT> discloses a light route control member comprising a first substrate, a first electrode disposed on the first substrate, a second substrate disposed on the first substrate and a second electrode disposed under the second substrate. <CIT> discloses a light beam direction control device is provided with a transparent substrates in which main surfaces of the transparent substrate are opposed to each other, transparent conductive films respectively disposed on the main surface side ofthe transparent substrate, electrodes electrically connected to the transparent conductive films, a control circuit for controlling a potential difference between the transparent conductive films and a plurality of light beam transmitting regions arranged on the transparent substrates, light beam absorbing regions disposed between the adjacent light beam transmitting regions, and the transparent conductive films. When shifting the range of outgoing direction of light beam to a narrow state, the control circuit applies the electrodes electrically open and holds the open state. <CIT> discloses a light transmittance changeable film. The light transmittance changeable film includes: an upper electrode; a conductive material layer which is formed in a linear pattern; a lower electrode which is located to face and be separated from the upper electrode; and an ink receptive layer which includes a micro space divided by a partition, receives an ink including a colored charge carrier inside the micro space, and is located between the upper electrode and the lower electrode. A light-shielding film shields transmitting of light from a light source, and is attached to a front surface of a display panel which is a display device used for a mobile phone, a notebook, a tablet PC, a vehicle navigation device, a vehicle touch, etc., so that the light-shielding film adjusts a viewing angle of light according to an incident angle of light to express a clear image quality at a viewing angle needed by a user when the display transmits a screen.

In addition, the light-shielding film may be used for the window of a vehicle, building or the like to shield outside light partially to prevent glare, or to prevent the inside from being visible from the outside.

That is, the light-shielding film may be a light route control member that controls a movement path of light, block light in a specific direction, and transmit light in a specific direction. Accordingly, by controlling the light transmission angle by the light-shielding film, it is possible to control the viewing angle of the user.

Meanwhile, such a light-shielding film may be a light-shielding film that can always control the viewing angle regardless of the surrounding environment or the user's environment, and switchable light-shielding film that allows the user to turn on/off the viewing angle control according to the surrounding environment or the user's environment may be distinguished.

Such a switchable light-shielding film may be implemented by adding electrically moving particles to the receiving part in which the light conversion material is disposed, and changing the receiving part into a light transmitting part and a light blocking part by dispersion and aggregation of the particles.

Meanwhile, the receiving part may be divided into a plurality of receiving parts by a plurality of partition wall parts disposed between the receiving parts.

At this time, due to the difference in refractive index between the receiving part and the partition wall part, light may be refracted, reflected, and scattered at the interface between the receiving part and the partition wall part without being incident into the pattern part. Accordingly, there is a problem in that light in a specific angle range is transmitted without being shielded by the pattern part.

Accordingly, as described above, there is a need for a light route control member having a new structure capable of efficiently controlling a change in shielding characteristics due to a difference in refractive index between the partition wall part and the receiving part.

An embodiment relates to the light route control member having improved shielding properties by controlling the size of the refractive index of a receiving part and a partition wall part, and a display device including the same.

The light route control member according to the embodiment may control the refractive index of the partition wall part and the receiving part of the light conversion part.

In detail, it is possible to minimize the difference in refractive index between the partition wall part and the receiving part, so that light at the interface between the partition wall part and the receiving part is not incident to the interior of the receiving part, but is scattered, reflected, or refracted to prevent it from moving to the outside.

Accordingly, light is prevented from being scattered, reflected, or refracted at the interface between the partition wall part and the receiving part, and the light is absorbed by being incident into the receiving part. Accordingly, the transmittance of light transmitted in the lateral direction of the light route control member may be controlled within a desired range.

Accordingly, it is possible to improve the lateral shielding effect of the light route control member by controlling the transmittance in a specific angle range.

In addition, the partition wall part is defined as a first partition wall part below the receiving part and a second partition wall part between the receiving parts. By controlling the refractive index of the first partition wall part to be less than or equal to the refractive index of the second partition wall part, total reflection at the interface between the first partition wall part and the second partition wall part is minimized, and loss of incident light due to total reflection can be minimized.

Accordingly, the front luminance of the light route control member according to the embodiment may be improved.

In addition, unless expressly otherwise defined and described, the terms used in the embodiments of the present invention (including technical and scientific terms) may be construed the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, and the terms such as those defined in commonly used dictionaries may be interpreted as having a meaning that is consistent with their meaning in the context of the relevant art.

In addition, the terms used in the embodiments of the present invention are for describing the embodiments and are not intended to limit the present invention. In this specification, the singular forms may also include the plural forms unless specifically stated in the phrase, and may include at least one of all combinations that may be combined in A, B, and C when described in "at least one (or more) of A (and), B, and C".

Further, in describing the elements of the embodiments of the present invention, the terms such as first, second, A, B, (a), and (b) may be used. These terms are only used to distinguish the elements from other elements, and the terms are not limited to the essence, order, or order of the elements.

In addition, when an element is described as being "connected", "coupled", or "connected" to another element, it may include not only when the element is directly "connected" to, "coupled" to, or "connected" to other elements, but also when the element is "connected", "coupled", or "connected" by another element between the element and other elements.

Further, when described as being formed or disposed "on (over)" or "under (below)" of each element, the "on (over)" or "under (below)" may include not only when two elements are directly connected to each other, but also when one or more other elements are formed or disposed between two elements.

Furthermore, when expressed as "on (over)" or "under (below)", it may include not only the upper direction but also the lower direction based on one element.

Hereinafter, a light route control member according to an embodiment will be described with reference to drawings. The light route control member described below relates to a switchable light route control member that drives in various modes according to the movement of electrophoretic particles application of a voltage.

Referring to <FIG>, a light route control member according to an embodiment includes a first substrate <NUM>, a second substrate <NUM>, a first electrode <NUM>, a second electrode <NUM>, and a light conversion part <NUM>.

The first substrate <NUM> may support the first electrode <NUM>. The first substrate <NUM> may be rigid or flexible.

In addition, the first substrate <NUM> may be transparent. For example, the first substrate <NUM> may include a transparent substrate capable of transmitting light.

The first substrate <NUM> may include glass, plastic, or a flexible polymer film. For example, the flexible polymer film may be made of any one of polyethylene terephthalate (PET), polycarbonate (PC), acrylonitrile-butadiene-styrene copolymer (ABS), polymethyl methacrylate (PMMA), polyethylene naphthalate (PEN), polyether sulfone (PES), cyclic olefin copolymer (COC), triacetylcellulose (TAC) film, polyvinyl alcohol (PVA) film, polyimide (PI) film, and polystyrene (PS), which is only an example, but the embodiment is not limited thereto.

In addition, the first substrate <NUM> may be a flexible substrate having flexible characteristics.

Further, the first substrate <NUM> may be a curved or bended substrate. That is, the light route control member including the first substrate <NUM> may also be formed to have flexible, curved, or bent characteristics. Accordingly, the light route control member according to the embodiment may be changed to various designs.

The first substrate <NUM> may have a thickness of <NUM> to <NUM>.

The first electrode <NUM> may be disposed on one surface of the first substrate <NUM>. In detail, the first electrode <NUM> may be disposed on an upper surface of the first substrate <NUM>. That is, the first electrode <NUM> may be disposed between the first substrate <NUM> and the second substrate <NUM>.

The first electrode <NUM> may contain a transparent conductive material. For example, the first electrode <NUM> may contain a metal oxide such as indium tin oxide, indium zinc oxide, copper oxide, tin oxide, zinc oxide, titanium oxide, etc..

The first electrode <NUM> may be disposed on the first substrate <NUM> in a film shape. In detail, light transmittance of the first electrode <NUM> may be about <NUM>% or more.

The first electrode <NUM> may have a thickness of about <NUM> to about <NUM>.

Alternatively, the first electrode <NUM> may contain various metals to realize low resistance. For example, the first electrode <NUM> may contain at least one metal of chromium (Cr), nickel (Ni), copper (Cu), aluminum (Al), silver (Ag), molybdenum (Mo). gold (Au), titanium (Ti), and alloys thereof.

The first electrode <NUM> may be disposed on the entire surface of one surface of the first substrate <NUM>. In detail, the first electrode <NUM> may be disposed as a surface electrode on one surface of the first substrate <NUM>. However, the embodiment is not limited thereto, and the first electrode <NUM> may be formed of a plurality of pattern electrodes having a predetermined pattern.

For example, the first electrode <NUM> may include a plurality of conductive patterns. In detail, the first electrode <NUM> may include a plurality of mesh lines intersecting each other and a plurality of mesh openings formed by the mesh lines.

Accordingly, even though the first electrode <NUM> contains a metal, visibility may be improved because the first electrode is not visible from the outside. In addition, the light transmittance is increased by the openings, so that the brightness of the light route control member according to the embodiment may be improved.

The second substrate <NUM> may be disposed on the first substrate <NUM>. In detail, the second substrate <NUM> may be disposed on the first electrode <NUM> on the first substrate <NUM>.

The second substrate <NUM> may contain a material capable of transmitting light. The second substrate <NUM> may contain a transparent material. The second substrate <NUM> may contain a material the same as or similar to that of the first substrate <NUM> described above.

For example, the second substrate <NUM> may include glass, plastic, or a flexible polymer film. For example, the flexible polymer film may be made of any one of polyethylene terephthalate (PET), polycarbonate (PC), acrylonitrile-butadiene-styrene copolymer (ABS), polymethyl methacrylate (PMMA), polyethylene naphthalate (PEN), polyether sulfone (PES), cyclic olefin copolymer (COC), triacetylcellulose (TAC) film, polyvinyl alcohol (PVA) film, polyimide (PI) film, and polystyrene (PS), which is only an example, but the embodiment is not limited thereto.

In addition, the second substrate <NUM> may be a flexible substrate having flexible characteristics.

Further, the second substrate <NUM> may be a curved or bended substrate. That is, the light route control member including the second substrate <NUM> may also be formed to have flexible, curved, or bent characteristics. Accordingly, the light route control member according to the embodiment may be changed to various designs.

The second substrate <NUM> may have a thickness of <NUM> to <NUM>.

The second electrode <NUM> may be disposed on one surface of the second substrate <NUM>. In detail, the second electrode <NUM> may be disposed on a lower surface of the second substrate <NUM>. That is, the second electrode <NUM> may be disposed on a surface on which the second substrate <NUM> faces the first substrate <NUM>. That is, the second electrode <NUM> may be disposed facing the first electrode <NUM> on the first substrate <NUM>. That is, the second electrode <NUM> may be disposed between the first electrode <NUM> and the second substrate <NUM>.

The second electrode <NUM> may contain a transparent conductive material. For example, the second electrode <NUM> may contain a metal oxide such as indium tin oxide, indium zinc oxide, copper oxide, tin oxide, zinc oxide, titanium oxide, etc..

The second electrode <NUM> may be disposed on the first substrate <NUM> in a film shape. In addition, the light transmittance of the second electrode <NUM> may be about <NUM>% or more.

The second electrode <NUM> may have a thickness of about <NUM> to about <NUM>.

Alternatively, the second electrode <NUM> may contain various metals to realize low resistance. For example, the second electrode <NUM> may contain at least one metal of chromium (Cr), nickel (Ni), copper (Cu), aluminum (Al), silver (Ag), molybdenum (Mo). gold (Au), titanium (Ti), and alloys thereof.

The second electrode <NUM> may be disposed on the entire surface of one surface of the second substrate <NUM>. In detail, the second electrode <NUM> may be disposed as a surface electrode on one surface of the second substrate <NUM>. However, the embodiment is not limited thereto, and the second electrode <NUM> may be formed of a plurality of pattern electrodes having a predetermined pattern.

For example, the second electrode <NUM> may include a plurality of conductive patterns. In detail, the second electrode <NUM> may include a plurality of mesh lines intersecting each other and a plurality of mesh openings formed by the mesh lines.

Accordingly, even though the second electrode <NUM> contains a metal, visibility may be improved because the second electrode <NUM> is not visible from the outside. In addition, the light transmittance is increased by the openings, so that the brightness of the light route control member according to the embodiment may be improved.

The light conversion part <NUM> is disposed between the first substrate <NUM> and the second substrate <NUM>. In detail, the light conversion part <NUM> is disposed between the first electrode <NUM> and the second electrode <NUM>.

Referring to <FIG>, a buffer layer <NUM> for improving adhesion between the light conversion part <NUM> and the first electrode <NUM> is disposed between the light conversion part <NUM> and the first electrode <NUM>. And, the light conversion part <NUM> and the second electrode <NUM>, which are different materials, may be easily adhered to each other through the buffer layer <NUM>.

In addition, the adhesive layer <NUM> may be disposed between the light conversion part <NUM> and the second electrode <NUM>. The light conversion part and the second electrode <NUM> may be adhered through the adhesive layer <NUM>.

The light conversion part <NUM> includes a partition wall part <NUM> and a receiving part <NUM>.

The partition wall part <NUM> may be defined as a partition wall region that partitions the receiving part. That is, the partition wall part <NUM> is a partition wall region partitioning a plurality of receiving parts. And the receiving part <NUM> may be defined as a region that changes into a light blocking part and a light transmitting part according to the application of a voltage.

The partition wall part <NUM> and the receiving part <NUM> are alternately disposed with each other. The partition wall part <NUM> and the receiving part <NUM> may be disposed to have different widths. For example, the width of the partition wall portion <NUM> may be greater than the width of the receiving part <NUM>.

The partition wall part <NUM> and the receiving part <NUM> are alternately disposed with each other. In detail, the partition wall part <NUM> and the receiving part <NUM> may be alternately disposed with each other. That is, each of the partition wall portions <NUM> may be disposed between the receiving parts <NUM> adjacent to each other, and each of the receiving parts <NUM> may be disposed between the adjacent partition wall portions <NUM>.

The partition wall part <NUM> may contain a transparent material. The partition wall part <NUM> may contain a material that may transmit light.

The partition wall part <NUM> may contain a resin material. The partition wall part <NUM> may contain a photo-curable resin material. As an example, the partition wall part <NUM> may contain a UV resin or a transparent photoresist resin. Alternatively, the partition wall part <NUM> may contain urethane resin or acrylic resin.

The partition wall part <NUM> may transmit light incident on any one of the first substrate <NUM> and the second substrate <NUM> toward another substrate.

For example, in <FIG>, light may be emitted in the direction of the second substrate <NUM> and may be incident in the direction of the first substrate <NUM>. The partition wall part <NUM> transmits the light, and the transmitted light may move in the direction of the second substrate <NUM>.

A sealing part <NUM> sealing the light route control member may be disposed on a side surface of the partition wall part, and a side surface of the light conversion part <NUM> may be sealed by the sealing part.

The receiving part <NUM> includes a light conversion material <NUM> including a dispersion 320a and light conversion particles 320b. In detail, the dispersion 320a may be filled in the receiving part <NUM>, and a plurality of light conversion particles 320b may be dispersed in the dispersion 330a.

The dispersion 320a may be a material for dispersing the light conversion particles 320b. The dispersion 320a may contain a transparent material. The dispersion 320a may contain a non-polar solvent. In addition, the dispersion 320a may contain a material capable of transmitting light. For example, the dispersion 320a may include at least one of a halocarbonbased oil, a paraffin-based oil, and isopropyl alcohol.

The light conversion particles 320b may be disposed to be dispersed in the dispersion 330a. In detail, the plurality of light conversion particles 320b may be disposed to be spaced apart from each other in the dispersion 330a.

The light conversion particles 320b may include a material capable of absorbing light. That is, the light conversion particle 320b may be a light absorbing particle. The light conversion particle 320b may have a color. For example, the light conversion particles 320b may have a black-based color. For example, the light conversion particles 320b may include carbon black particles.

The surface of the light conversion particle 320b may be charged. Accordingly, according to the application of the voltage, the light conversion particles 320b may move in one direction.

The light transmittance of the receiving part <NUM> may be changed by the light conversion particles 320b. In detail, the receiving part <NUM> may be changed into a light blocking part and a light transmitting part by changing the light transmittance by the light conversion particles 320b. That is, the receiving part <NUM> may change the transmittance of the light passing through the receiving part <NUM> by dispersion and aggregation of the light conversion particles 320b disposed therein in the dispersion 320a.

For example, the light path member according to the embodiment may be change from the first mode to the second mode or from the second mode to the first mode by a voltage applied to the first electrode <NUM> and the second electrode <NUM>.

In detail, in the light route control member <NUM> according to the embodiment, the receiving part <NUM> becomes the light blocking part in the first mode, and light of a specific angle may be blocked by the receiving part <NUM>. That is, a viewing angle of the user viewing from the outside may be narrowed.

In addition, in the light route control member <NUM> according to the embodiment, the receiving part <NUM> becomes the light transmitting part in the second mode, and in the light route control member according to the embodiment, light may be transmitted through both the partition wall part <NUM> and the receiving part <NUM>. That is, the viewing angle of the user viewing from the outside may be widened.

Switching from the first mode to the second mode, that is, the conversion of the receiving part <NUM> from the light blocking part to the light transmitting part may be realized by movement of the light conversion particles 320b of the receiving part <NUM>. That is, the light conversion particles 320b have electric charges on their surface, and may move in the direction of the first electrode <NUM> or the second electrode <NUM> by an applied voltage or by characteristics of the charge. That is, the light conversion particles 320b are electrophoretic particles.

In detail, the receiving part <NUM> may be electrically connected to the first electrode <NUM> and the second electrode <NUM>.

In this case, when a voltage is not applied to the light route control member from the outside, the light conversion particles 320b of the receiving part <NUM> are uniformly dispersed in the dispersion 330a, and light may be blocked by the light conversion particles in the receiving part <NUM>. Accordingly, in the first mode, the receiving part <NUM> may be driven as the light blocking part.

Alternatively, when a voltage is applied to the light route control member from the outside, the light conversion particles 320b may move. For example, the light conversion particles 320b may move toward one end or the other end of the receiving part <NUM> by a voltage transmitted through the first electrode <NUM> and the second electrode <NUM>. That is, the light conversion particles 320b may move from the receiving part <NUM> toward the first electrode or the second electrode.

In detail, when a voltage is applied to the first electrode <NUM> and/or the second electrode <NUM>, an electric field is formed between the first electrode <NUM> and the second electrode <NUM>. And, the light conversion particles 320b in a negatively charged state can be moved in the direction of the positively charged electrode among the first electrode <NUM> and the second electrode <NUM> using the dispersion 320a as a medium.

In detail, when a voltage is applied to the first electrode <NUM> and/or the second electrode <NUM>, an electric field is formed between the first electrode <NUM> and the second electrode <NUM>, and the charged carbon black, that is, the light conversion particles may be moved toward a positive electrode of the first electrode <NUM> and the second electrode <NUM> using the dispersion 320a as a medium.

That is, when the voltage is applied to the first electrode <NUM> and/or the second electrode <NUM>, as shown in <FIG>, the light conversion particles 320b may be moved toward the first electrode <NUM> in the dispersion 330a. That is, the light conversion particles 320b are moved in one direction, and the receiving part <NUM> may be driven as the light transmitting part.

In addition, when the voltage is not applied to the first electrode <NUM> and/or the second electrode <NUM>, as shown in <FIG>, the light conversion particles 320b may be uniformly dispersed in the dispersion 320a to drive the receiving part <NUM> as the light blocking part.

Accordingly, the light route control member according to the embodiment may be driven in two modes according to a user's surrounding environment. That is, when the user requires light transmission only at a specific viewing angle, the receiving unit is driven as the light blocking part, or in an environment in which the user requires high brightness, a voltage may be applied to drive the receiving unit as the light transmitting part.

Therefore, since the light route control member according to the embodiment may be implemented in two modes according to the user's requirement, the light route control member may be applied regardless of the user's environment.

Meanwhile, in order to improve the shielding characteristics of the light route control member, the partition wall part <NUM> and the receiving part <NUM> may control refractive indices of the partition wall part <NUM> and the receiving part <NUM>. In detail, the difference in refractive index between the partition wall part <NUM> and the receiving part <NUM> may be controlled in order to improve the shielding characteristics of the light route control member.

For example, the refractive index of the partition wall part <NUM> may be <NUM> or less. According to the claimed invention, the refractive index of the partition wall part <NUM> is <NUM> to <NUM>. The refractive index of the partition wall part <NUM> may correspond to the refractive index of the resin composition constituting the partition wall part.

In addition, the refractive index of the receiving part <NUM> may be <NUM> or less. According to the claimed invention, the refractive index of the receiving part <NUM> is <NUM> to <NUM>. The refractive index of the receiving part <NUM> may correspond to the refractive index of the dispersion 320a contained in the receiving part <NUM>.

In this case, the refractive indices of the partition wall part <NUM> and the receiving part <NUM> may be the same or different from each other. For example, the refractive index of the partition wall part <NUM> may be the same as, smaller than, or greater than the refractive index of the receiving part <NUM>.

In detail, the ratio of the refractive indices of the partition wall part <NUM> and the receiving part <NUM> may be <NUM>:<NUM> to <NUM>:<NUM>. That is, the ratio of the refractive indices of the partition wall part <NUM> and the receiving part <NUM> may have the size ratio within the size range of the refractive indices of the partition wall part <NUM> and the receiving part <NUM>.

The ratio of the refractive indices of the partition wall part <NUM> and the receiving part <NUM> is <NUM>:<NUM> to <NUM>:<NUM>, so that diffraction, reflection, and refraction of light passing through the light conversion part <NUM> can be minimized. In detail, by minimizing the difference in refractive index between the partition wall part <NUM> and the receiving part <NUM>, diffraction, reflection or refracting of light at the interface between the partition wall part <NUM> and the receiving part <NUM> is may be minimized.

Accordingly, the light incident from the partition wall part to the receiving part is not diffracted, reflected, or refracted at the interface between the partition wall part and the receiving part. Accordingly, it is possible to minimize the light from being absorbed by the receiving part and transmitted to the outside. Thereby, the shielding characteristic of the light route control member can be improved.

That is, in the first mode in which the receiving part <NUM> becomes a light blocking part, and blocks the light of a specific angle by the receiving part320, diffraction, reflection, or refracting of light at the interface between the partition wall part and the receiving part may be minimized due to a difference in refractive index between the partition wall part and the receiving part. Accordingly, in the first mode, by diffracting, reflecting, or refracting light at the interface between the partition wall part and the receiving part, the light is not blocked and transmitted at different angles can be minimized. Thereby, the shielding characteristic of the light route control member can be improved.

Meanwhile, the refractive index of the partition wall part <NUM> and the refractive index of the receiving part <NUM> may have different sizes.

For example, the refractive index of the partition wall part <NUM> may be greater than that of the receiving part <NUM>. In detail, the refractive index of the receiving part may be greater than that of the receiving part <NUM> and may be <NUM> times or less of the refractive index of the receiving part.

When the refractive index of the partition wall part exceeds <NUM> times the refractive index of the receiving part, due to a difference in refractive index between the partition wall part and the receiving part, the light may be refracted or scattered at the interface between the partition wall part and the receiving part, so that the blocking characteristic may be deteriorated.

In addition, since the refractive index of the partition wall part is greater than or equal to the size of the refractive index of the receiving part, total reflection of light moving from the partition wall part in the direction of the receiving part may be prevented. In addition, it is possible to prevent light in a specific angular direction from being transmitted without being absorbed by the receiving part.

In the light path control member, the refractive index of the partition wall part is greater than that of the receiving part <NUM> and is <NUM> times or less of the refractive index of the receiving part. Accordingly, the light route control member may reduce the transmittance of light transmitted at a specific angle, thereby improving the side shielding effect.

In detail, the light route control member controls the transmittance of the light transmitted at an angle of <NUM>° with respect to the upper surface of the light conversion part <NUM> to be <NUM>% or less, in detail, in the range of <NUM>% to <NUM>%. Thereby, the side shielding effect can be improved.

In addition, the light route control member controls the transmittance of the light transmitted at an angle of <NUM>° and <NUM>° with respect to the upper surface of the light conversion part <NUM> to be <NUM>% or less, in detail, in the range of <NUM>% to <NUM>%. Thereby, the side shielding effect can be improved.

That is, the light route control member according to the embodiment may control the difference in refractive index between the partition wall part and the receiving part within a certain size range, thereby improving the shielding characteristics of light shielded through the receiving part. That is, at the interface between the partition wall part and the receiving part, light is not incident into the receiving part, and transmission of light by refraction, scattering, or reflection can be minimized. Accordingly, it is possible to reduce the transmittance of light at a specific angle, that is, a side angle.

Accordingly, the content of particles in the receiving part may be reduced, and the lateral transmittance may be reduced, thereby shortening the driving time of the light route control member.

Meanwhile, referring to <FIG>, the partition wall part <NUM> is defined as a first partition wall part 310a and a second partition wall part 310b according to positions.

The first partition wall part 310a is defined as a region between the first electrode <NUM> and the receiving part <NUM>. That is, the first partition wall part 310a is defined as a region between the upper surface of the first electrode <NUM> and the lower surface of the receiving part <NUM> among the partition wall regions.

Also, the second partition wall part 310b is defined as a region between the first partition wall part 310a and the second electrode <NUM>. That is, the second partition wall part 310b is defined as an area between the receiving parts <NUM> in the area between the first partition wall part 310a and the second electrode <NUM> among the partition wall areas.

In addition, the first partition wall part 310a and the second partition wall part 310b are defined as relative positions of the first electrode <NUM> and the second electrode <NUM>.

In detail, the first partition wall part 310a are defined as a partition wall part disposed closer to the first electrode <NUM> than the second electrode <NUM>, and the second partition wall part 310b is the first electrode, and the second partition wall part 310b is defined as a partition wall part disposed closer to the second electrode than the first electrode <NUM>.

The first partition wall portion 310a is a base partition wall portion disposed close to the first electrode, and the second partition wall portion 310b is a separation partition wall portion disposed close to the second electrode.

The first partition wall part 310a and the second partition wall part 310b have different refractive indices. In detail, the refractive index of the second partition wall portion 310b may be less than that of the first partition wall portion 310a.

That is, when the light passing through the light route control member according to the embodiment is transmitted from the direction of the second substrate to the direction of the first substrate, the refractive index of the second partition wall part 310b through which the light first passes may be less than that of the first partition wall part 310a.

Accordingly, since the light passing through the light conversion part of the light route control member moves from a region having a low refractive index to a region having a high refractive index, total reflection of light may be prevented, thereby reducing light loss due to total reflection.

In addition, the first partition wall part 310a, the second partition wall part 310b, and the receiving part <NUM> have different refractive indices. The ratio of the first partition wall part 310a, the second partition wall part 310b, and the receiving part <NUM> satisfies a range of <NUM> to <NUM>:<NUM> to <NUM>: <NUM>.

Accordingly, the difference in refractive index between the first and second partition walls 310a and 310b is controlled to prevent total reflection at the interface between the first and second partition walls 310a and 310b is prevented. Thereby, it is possible to improve the front luminance. And, refraction, scattering, or reflection of light at the interface between the second partition wall part 310b and the receiving part <NUM> can be prevented by controlling the difference in refractive index between the second partition wall part 310b and the receiving part <NUM>. Accordingly, it is possible to reduce the transmittance of light transmitted at a specific angle. Thereby, the side shielding effect of the light route control member can be improved.

<FIG> are views illustrating other cross-sectional views of a light route control member according to an embodiment.

Referring to <FIG>, in the light route control member according to the embodiment, the receiving part <NUM> may be disposed in contact with the electrode differently from <FIG>.

For example, the receiving part <NUM> may be disposed in direct contact with the first electrode <NUM>.

Accordingly, since the first electrode <NUM> and the receiving part <NUM> are not spaced apart and are arranged in direct contact with each other, the voltage applied from the first electrode <NUM> may be easily transferred to the receiving part <NUM>.

Accordingly, the moving speed of the light conversion particle 320b inside the receiving part <NUM> may be improved, and thus the driving characteristics of the light route control member may be improved.

In addition, referring to <FIG>, in the light route control member according to the embodiment, unlike <FIG>, the receiving part <NUM> may be disposed while having a constant inclination angle θ.

In detail, referring to <FIG>, the receiving part <NUM> may be disposed while having an inclination angle θ of greater than <NUM>° to less than <NUM>° with respect to the first electrode <NUM>. In detail, the receiving part <NUM> may extend upwardly while having an inclination angle θ of greater than <NUM>° to less than <NUM>° with respect to one surface of the first electrode <NUM>.

Accordingly, when the light route member is used together with the display panel, moire caused by the overlapping phenomenon between the pattern of the display panel and the receiving part <NUM> of the light route member may be prevented, thereby improving user visibility.

Hereinafter, a light route control member according to another embodiment will be described with reference to <FIG>. In the description of the light route control member according to another embodiment, descriptions that are similar to those of the light route control member according to the above-described embodiment will be omitted, and the same reference numerals will be given to the same components.

As described above, a buffer layer <NUM> for easy adhesion between the first electrode <NUM> and the light conversion part <NUM> may be disposed between the first electrode <NUM> and the light conversion part <NUM>.

The buffer layer <NUM> may have conductivity. In detail, the buffer layer <NUM> disposed on the first electrode <NUM> may have conductivity. Accordingly, when an electrode is additionally disposed on the buffer layer <NUM>, the current applied from the first electrode <NUM> may flow to the additional electrode through the buffer layer <NUM>.

Referring to <FIG>, the buffer layer <NUM> may include conductive particles <NUM>. In detail, the buffer layer may include a plurality of conductive particles. That is, the buffer layer <NUM> may be formed by stacking a plurality of conductive particles <NUM>.

The conductive particles <NUM> may be formed of nano-sized particles. In detail, the conductive particles <NUM> may be formed to have a particle diameter of <NUM> or less. In detail, the conductive particles <NUM> may be formed to have a particle diameter of <NUM> to <NUM>.

When the particle diameter of the conductive particles <NUM> exceeds <NUM>, the conductivity of the buffer layer of a certain thickness may be reduced. Accordingly, in order to satisfy the conductivity of a certain size, the thickness of the buffer layer may be increased to increase the overall thickness of the light route control member.

The conductive particles <NUM> may include an inorganic material. In detail, the conductive particles <NUM> may include a metal oxide such as titanium dioxide (TiO2), zinc oxide (ZnO2), germanium oxide (GeO2), and molybdenum dioxide (MoO2).

Since the conductive particles <NUM> include metal oxide particles, the buffer layer <NUM> can be easily applied on the first electrode <NUM> including a metal, and can be easily adhered to the buffer layer <NUM>.

The buffer layer <NUM> may have conductivity due to a plurality of conductive particles constituting the buffer layer <NUM>. Accordingly, even when a connection electrode for connecting an external power source is directly disposed on the buffer layer <NUM>, electricity may be conducted with the first electrode <NUM> through the buffer layer <NUM>.

A functional group (R) may be connected to an end of the conductive particle <NUM>. In detail, a hydrophilic functional group may be connected to an end of the conductive particle <NUM>. In more detail, hydrophilic functional groups of -NH, -OH, and -COOH may be connected to the ends of the conductive particles <NUM>.

The buffer layer <NUM> may be formed by immersing the first substrate on which the first electrode is disposed in a precursor solution forming the buffer layer.

In detail, first, the precursor material forming the buffer layer may be mixed with water to react the precursor material with water. As an example, the buffer layer may include titanium dioxide conductive particles. Hereinafter, a process of forming the titanium dioxide conductive particles will be mainly described.

The precursor material may include Tetra isopropyl titanate (TTIP), Tetrabutyl titanate (TBT), or Titanium tetrachloride (TiCl4) represented by the following structural formula. <CHM>
<CHM>
<CHM>.

These precursor materials can be mixed with water to react with water. In this case, the reaction between the precursor material and water may proceed by the following mechanism.

That is, the precursor material may react with water to be converted into Ti-OH, which is easily combined, and may undergo condensation polymerization with TiO2.

In this case, the -OH group is exposed through the unreacted portion, so that the conductive particles may have hydrophilicity. The amount of the -OH group can be controlled according to the synthesis conditions, and the degree of hydrophilicity can be controlled by changing the synthesis conditions according to the degree of hydrophilicity to be implemented.

Then, the first substrate on which the first electrode is disposed is immersed in a solution in which the precursor material and water are mixed, and then heated at a temperature of about <NUM>° C. to about <NUM>° C. for about <NUM> minutes to about <NUM> minutes. Accordingly, a buffer layer including conductive particles to which the hydrophilic functional group is bonded may be formed on the first electrode.

Then, the surface of the buffer layer may be washed with ethanol to finally form the buffer layer.

Since the buffer layer <NUM> includes the conductive particles <NUM> having the hydrophilic functional group, adhesion to the resin material constituting the light conversion part disposed on the first electrode <NUM> may be improved.

That is, since the buffer layer <NUM> includes a metal material that is the same material as the first electrode, adhesion with the first electrode can be improved. Also, since the buffer layer <NUM> includes conductive particles having hydrophilicity, it is possible to improve adhesion with a resin material constituting the light conversion part.

Accordingly, the first electrode, which is a heterogeneous material, and the resin material constituting the light conversion part are adhered through the buffer layer <NUM>, thereby improving the adhesion between the first electrode and the resin material.

In addition, since the buffer layer <NUM> has conductivity, a separate process for removing the buffer layer may not be required to form a connection electrode connecting the external power source and the light route control member.

Referring to <FIG>, a connection electrode for connecting an external power source and an light route control member may be disposed on the first substrate <NUM>.

The connection electrode may include a first connection electrode <NUM> disposed on the first substrate <NUM> and a second connection electrode <NUM> disposed under the second substrate <NUM>.

The first connection electrode <NUM> may be disposed on the buffer layer <NUM> disposed on the first substrate <NUM>. The first connection electrode <NUM> may be disposed in direct contact with the buffer layer <NUM>.

Also, the second connection electrode <NUM> may be disposed under the second substrate <NUM>. The second connection electrode <NUM> may include the same material as the second electrode <NUM>. In detail, the second connection electrode <NUM> may be integrally formed with the second electrode <NUM>. That is, the second connection electrode <NUM> may be formed by removing a portion of the adhesive layer <NUM> as a pad portion of the second electrode <NUM> to expose the second electrode <NUM>. The connection electrode <NUM> may include a conductive material. For example, the first connection electrode <NUM> may be formed by applying a silver (Ag) paste on the buffer layer <NUM>.

A wire connected to an external power supply may be connected to the first connection electrode <NUM> and the second connection electrode <NUM>. Accordingly, the voltage applied from the external power supply is transmitted to the light route control member through the first connection electrode <NUM> and the second connection electrode <NUM>, and the voltage can be applied to the inside of the receiving part.

On the other hand, the buffer layer <NUM> may be formed in a certain thickness range to conduct electricity between the connection electrode and the electrode. In detail, the buffer layer <NUM> may be formed to a thickness of about <NUM> or less.

When the thickness of the buffer layer <NUM> exceeds about <NUM>, the resistance of the buffer layer <NUM> may increase due to an increase in the thickness of the buffer layer <NUM>, and thus conductivity of the buffer layer may be reduced.

The light route control member according to another embodiment may include a buffer layer disposed between the light conversion part including the resin material and the electrode including the metal material.

Accordingly, it is possible to prevent a decrease in adhesive strength due to the dissimilar material when the light conversion part and the electrode are bonded to each other.

That is, since the buffer layer including conductive metal particles improves adhesion to the electrode, which is the same material, the conductive particles constituting the buffer layer include a hydrophilic functional group that improves adhesion to the resin material. Accordingly, it is possible to improve the adhesion to the light conversion part including the resin material.

Accordingly, when the light conversion part and the electrode, which are different materials, are bonded to each other, adhesive properties can be improved, and thus, it is possible to prevent the light conversion part from being removed from the electrode, thereby reducing reliability.

In addition, since the buffer layer includes conductive metal particles, when disposing the connection electrode connecting the light route control member and the external power supply, the connection electrode may be disposed directly on the buffer layer.

That is, a separate process for removing the buffer layer may be omitted by directly disposing the connection electrode on the buffer layer without removing the buffer layer.

In addition, it is possible to prevent stains generated while removing the buffer layer. Accordingly, it is possible to improve visibility by preventing the stains in the process from being visually recognized from the outside.

Hereinafter, the present invention will be described in more detail through the transmittance of the light route control member according to the embodiments. These embodiments are merely presented as examples in order to explain the present invention in more detail. Therefore, the present invention is not limited to these examples.

A light path control member was manufactured.

In detail, the first electrode was disposed on the first substrate, and the second electrode was disposed on the second substrate. Then, a light conversion part including a partition wall part and a receiving part was disposed on the first electrode and adhered, and the second substrate and the second electrode is disposed and adhered on the light conversion part to form a light route control member.

At this time, the size of the refractive index of the receiving part is <NUM>, and the size of the refractive index of the partition wall is <NUM>.

Then, the lateral transmittance of the light route control member at <NUM>°, <NUM>°, <NUM>°, <NUM>°, and <NUM>° was measured.

After the light route control member was manufactured in the same manner as in Example <NUM>, except that the size of the refractive index of the partition wall part is <NUM>. Then, the lateral transmittance of the light path control member at <NUM>°, <NUM>°, <NUM>°, <NUM>°, and <NUM>° was measured.

Referring to Table <NUM>, the light route control member according to the embodiments may effectively control the lateral transmittance at <NUM>°, <NUM>°, <NUM>°, <NUM>°, and <NUM>°.

Especially. By effectively reducing the light transmittance of <NUM>°, which is the optimal viewing angle of the first mode for implementing the privacy mode, side shielding of the light route member can be effectively implemented in the first mode.

Hereinafter, referring to <FIG>, a display device and a display apparatus to which the light route control member according to an embodiment is applied will be described.

Referring to <FIG> and <FIG>, the light route control member <NUM> according to an embodiment may be disposed on a display panel <NUM>.

The display panel <NUM> and the light route control member <NUM> may be disposed to be adhered to each other. For example, the display panel <NUM> and the light route control member <NUM> may be adhered to each other via an adhesive layer <NUM>. The adhesive layer <NUM> may be transparent. For example, the adhesive layer <NUM> may include an adhesive or an adhesive layer containing an optical transparent adhesive material.

The adhesive layer <NUM> may include a release film. In detail, when adhering the light route control member and the display panel, the light route control member and the display panel may be adhered after the release film is removed.

The display panel <NUM> may include a first substrate <NUM> and a second substrate <NUM>. When the display panel <NUM> is a liquid crystal display panel, the display panel <NUM> may be formed in a structure in which the first substrate <NUM> including a thin film transistor (TFT) and a pixel electrode and the second substrate <NUM> including color filter layers are bonded with a liquid crystal layer interposed therebetween.

In addition, the display panel <NUM> may be a liquid crystal display panel of a color filter on transistor (COT) structure in which a thin film transistor, a color filter, and a black matrix are formed at the first substrate <NUM> and the second substrate <NUM> is bonded to the first substrate <NUM> with the liquid crystal layer interposed therebetween. That is, a thin film transistor may be formed on the first substrate <NUM>, a protective film may be formed on the thin film transistor, and a color filter layer may be formed on the protective film. In addition, a pixel electrode in contact with the thin film transistor may be formed on the first substrate <NUM>. At this point, in order to improve an aperture ratio and simplify a masking process, the black matrix may be omitted, and a common electrode may be formed to function as the black matrix.

In addition, when the display panel <NUM> is the liquid crystal display panel, the display device may further include a backlight unit providing light from a rear surface of the display panel <NUM>.

Alternatively, when the display panel <NUM> is an organic light emitting display panel, the display panel <NUM> may include a self-luminous element that does not require a separate light source. In the display panel <NUM>, a thin film transistor may be formed on the first substrate <NUM>, and an organic light emitting element in contact with the thin film transistor may be formed. The organic light emitting element may include an anode, a cathode, and an organic light emitting layer formed between the anode and the cathode. Further, the second substrate <NUM> configured to function as an encapsulation substrate for encapsulation may further be included on the organic light emitting element.

Furthermore, although not shown in drawings, a polarizing plate may be further disposed between the light route control member <NUM> and the display panel <NUM>. The polarizing plate may be a linear polarizing plate or an external light reflection preventive polarizing plate. For example, when the display panel <NUM> is a liquid crystal display panel, the polarizing plate may be the linear polarizing plate. Further, when the display panel <NUM> is the organic light emitting display panel, the polarizing plate may be the external light reflection preventive polarizing plate.

In addition, an additional functional layer <NUM> such as an anti-reflection layer, an anti-glare, or the like may be further disposed on the light route control member <NUM>. Specifically, the functional layer <NUM> may be adhered to one surface of first substrate <NUM> of the light route control member. Although not shown in drawings, the functional layer <NUM> may be adhered to the first substrate <NUM> of the light route control member via an adhesive layer. In addition, a release film for protecting the functional layer may be further disposed on the functional layer <NUM>.

Further, a touch panel may be further disposed between the display panel and the light route control member.

Although it is shown in the drawings that the light route control member is disposed at an upper portion of the display panel, but the embodiment is not limited thereto, and the light route control member may be disposed at various positions such as a position in which light is adjustable, that is, a lower portion of the display panel, between a second substrate and a first substrate of the display panel, or the like.

Referring to <FIG>, the light route control member according to the embodiment may be applied to a vehicle.

Referring to <FIG> and <FIG>, the light route control member according to the embodiment may be applied to a display device displaying a display.

For example, when power is not applied to the light route control member as shown in <FIG>, the receiving unit functions as the light blocking part, so that the display device is driven in a light blocking mode, and when power is applied to the light route control member as shown in <FIG>, the receiving unit functions as the light transmitting part, so that the display device may be driven in an open mode.

Accordingly, a user may easily drive the display device in a privacy mode or a normal mode according to application of power.

In addition, referring to <FIG>, the display device to which the light route control member according to the embodiment is applied may also be applied inside the vehicle.

For example, the display device including the light route control member according to the embodiment may display a video confirming information of the vehicle and a movement route of the vehicle. The display device may be disposed between a driver seat and a passenger seat of the vehicle.

In addition, the light route control member according to the embodiment may be applied to a dashboard that displays a speed, an engine, an alarm signal, and the like of the vehicle.

Furthermore, the light route control member according to the embodiment may be applied to a front glass (FG) of the vehicle or right and left window glasses.

The characteristics, structures, effects, and the like described in the above-described embodiments are included in at least one embodiment of the present invention, but are not limited to only one embodiment. Furthermore, the characteristic, structure, and effect illustrated in each embodiment may be combined or modified for other embodiments by a person skilled in the art. Accordingly, it is to be understood that such combination and modification are included in the scope of the present invention.

Claim 1:
A light route control member comprising:
a first substrate (<NUM>);
a first electrode (<NUM>) disposed on the first substrate (<NUM>);
a second substrate disposed on the first substrate (<NUM>);
a second electrode (<NUM>) disposed under the second substrate; and
a light modification part (<NUM>) disposed between the first electrode (<NUM>) and the second electrode (<NUM>) and adapted to change a viewing angle of a light transmitted through the light route control member,
wherein the light modification part (<NUM>) includes a partition wall part (<NUM>) and a receiving part (<NUM>) that are alternately arranged,
wherein a light transmittance of the light modification part is changed according to a voltage applied to the first electrode (<NUM>) and the second electrode (<NUM>),
wherein the receiving part (<NUM>) includes a dispersion (320a) and electrophoretic particles (320b) dispersed in the dispersion (320a),
wherein the partition wall part (<NUM>) includes a first partition wall part (310a) disposed closer to the first electrode (<NUM>) than the second electrode (<NUM>) and defined as a region between an upper surface of the first electrode (<NUM>) and a lower surface of the receiving part (<NUM>), and a second partition wall part (310b) disposed closer to the second electrode (<NUM>) than the first electrode (<NUM>) and defined as a region between a plurality of receiving parts (<NUM>) in a region between the first partition wall part (310a) and the second electrode (<NUM>) among the partition wall part (<NUM>), characterized in that a refractive index of the partition wall part (<NUM>) is <NUM> to <NUM>; a refractive index of the receiving part (<NUM>) is <NUM> to <NUM>;
wherein refractive indices of the first partition wall part (310a) and the second partition wall part (310b) and the receiving part (<NUM>) are different to each other, and
wherein a ratio of refractive index of the first partition wall part (310a), the second partition wall part (310b), and the receiving part (<NUM>) is <NUM>-<NUM>:<NUM>-<NUM>:<NUM>.