KR102758663B1 - Vehicles with self-customizable microLEDs - Google Patents

Abstract

The present invention relates to a vehicle equipped with self-customizable micro LEDs, which configures a transparent micro LED display skin on each panel of the vehicle so that the user can easily change the color of each panel configured with a transparent pique LED display skin to improve the beauty of the exterior, and which uses the transparent micro LED display skin configured on the front and rear of the vehicle to perform the roles of a headlamp, a position lamp, a rear lamp, and a reverse lamp. The present invention relates to a vehicle equipped with self-customizable micro LEDs, which configures a transparent micro LED display skin on one or a plurality of external surfaces of a front bumper panel, a bonnet panel, a front fender panel, a roof panel, a door panel, a tailgate panel, a rear fender panel, and a rear bumper panel of the vehicle, and configures a master unit and a remote slave that control the transparent micro LED display skin, and then uses a smartphone including an APP that can control the main control unit or the remote control unit of the master unit or the remote slave to easily change and control the color and pattern of the transparent micro LED display skin remotely.

Description

Vehicles with self-customizable microLEDs

The present invention relates to a vehicle equipped with self-customizable micro LEDs, and more specifically, to a vehicle equipped with self-customizable micro LEDs, which configures a transparent micro LED display skin on each panel of the vehicle so that a user can easily change the color of each panel on which the LED display skin is configured with a transparent peak to improve the beauty of the exterior, and which enables the transparent micro LED display skins configured on the front and rear of the vehicle to perform the functions of headlamps, position lamps, rear lamps, and reverse lamps.

Recently, automobiles have evolved beyond being a simple means of transportation to become a means of expressing one's individuality and emotions, and accordingly, the demand for vehicle accessories and tuning accessories attached to vehicles and the related market are gradually increasing.

A tuning culture is becoming active in which individuals purchase and install tuning parts to tune various parts installed in vehicles. Vehicles are equipped with various parts such as antennas, car audio, tires, wheels, and suspensions, and vehicle owners purchase tuning parts to tune these various parts and install them on their vehicles, thereby tuning their vehicles to their own tastes.

First, let's look at the existing technology:

Registration No. 10-2238168 (Special) A light output device equipped on or attachable to a vehicle, comprising: a first plate having a mounting groove formed in at least a portion of one surface; a light emitting module including a light emitting portion, the light emitting module being mounted in the mounting groove; and a second plate coupled with the first plate and including a printing area, wherein the light emitting portion of the light emitting module is coupled to the mounting groove of the first plate so as to emit light in a direction opposite to the surface coupled with the second plate, wherein the mounting groove includes a main groove formed to have a first length and a first width in a first direction; and at least one auxiliary groove formed to have a second length and a second width in a second direction inclined at a predetermined angle with respect to the first direction, wherein the auxiliary groove is formed continuously at one or both ends of the main groove.

Looking at the above-mentioned conventional technology, it mainly describes including a light emitting section of a first plate, forming a light output device by combining a second plate with the first plate, and then providing or attaching the light output device to a vehicle so that a lighting effect, etc. can be produced in the vehicle.

However, the above-mentioned conventional technology has a problem in that it may reduce the external appearance of existing vehicles due to the size and volume of the light output device composed of the first and second plates, it has a problem in that it is difficult for the user to remotely control the light output device, and since light is emitted in only a single color, there is a problem in that the design, etc., cannot help but be monotonous.

The present invention has been made to solve the problems of the above-mentioned prior art, and focuses on providing a vehicle equipped with a self-customizable micro LED, in which a transparent micro LED display skin is formed on one or more external surfaces of a front bumper panel, a bonnet panel, a front fender panel, a roof panel, a door panel, a tailgate panel, a rear fender panel, and a rear bumper panel of a vehicle, and a master unit and a remote slave for controlling the transparent micro LED display skin are formed, and then a user can remotely change and control the color and pattern of the transparent micro LED display skin using a smartphone including an APP that can control the main control unit or the remote control unit of the master unit or the remote slave.

According to the present invention for achieving the above-mentioned object, there is provided a vehicle; a transparent flexible substrate configured in the vehicle, the transparent micro LED display skin having transparency and flexibility, and a semiconductor device layer having micro LED pixels transferred and attached on the transparent flexible substrate, the transparent micro LED display skin being completely or partially coated on the surface of the vehicle; a master unit configured outside or inside the vehicle, the master unit including a power switch controlling a power supply unit, a charging port for charging a battery via a USB cable, a power supply unit controlled by the power switch, a battery for storing power charged by the charging port, and a wireless electric coil for wirelessly supplying power to the power supply unit, a short-range wireless communication unit for short-range wireless communication with an external device including a smartphone and other devices, a main control unit for controlling color expression in the transparent micro LED display skin of the vehicle, an energy harvesting unit for generating energy itself, and a light detection unit for detecting the brightness of external light of the vehicle; A remote slave configured at a position spaced apart from the master unit outside or inside the vehicle and including a wireless electric antenna for receiving power generated from the power wireless supply unit of the master unit, a remote control unit for driving and controlling the transparent micro LED display skin, a transmission and reception unit for ultra-close remote transmission and reception with the master unit, an energy harvesting unit for self-generating energy, and a light detection unit for detecting the outside and brightness; The present invention relates to a vehicle equipped with a self-customized micro LED, comprising: a smartphone including an APP that can control the main control unit or remote control unit of the master unit or remote slave through the above-described master unit, a short-range wireless communication unit, and a short-range wireless communication method; wherein the harvesting unit is composed of one or a combination of a photoelectric element, a pressure element, and a wireless electric conversion element; wherein the transparent micro LED display skin is controlled by a master unit or a remote slave that is close to the specific transparent micro LED display skin when the specific transparent micro LED display skin is controlled through the APP; and wherein the micro LED pixel is a compound semiconductor having a band gap as a p-n diode layer, and is configured by sequentially stacking a circuit pattern or bump, a positive electrode layer that serves as a conductive adhesive layer, a transparent conductive layer, a transparent p-electrode layer for power supply, a p-GaN layer, an active layer, an n-GaN layer, and a transparent n-GaN layer having electrical conductivity, wherein a transparent insulating layer is formed between each micro LED pixel. The vehicle comprises a front bumper panel, a bonnet, The transparent micro LED display skin is configured to include a panel, a front fender panel, a roof panel, a door panel, a tailgate panel, a rear fender panel, and a rear bumper panel, and the transparent micro LED display skin is configured on the outer surface of the front bumper panel, the bonnet panel, the front fender panel, the roof panel, the door panel, the tailgate panel, the rear fender panel, and the rear bumper panel of the vehicle, respectively, wherein a plurality of grooves are formed by being inserted into the front bumper panel, the bonnet panel, the front fender panel, the roof panel, the door panel, the tailgate panel, the rear fender panel, and the rear bumper panel of the vehicle, and the transparent micro LED display skin is configured in each of the grooves, and a plurality of grooves are formed by being inserted into the door panel at a predetermined interval from top to bottom, respectively, and the vertical width becomes narrower as it goes toward the bottom, and the vertical width of the groove located at the bottom of each groove formed in the door panel is greater than the vertical width of the groove located at the top thereof. Its technical characteristics include being formed at 80% size.

In addition, the vehicle is configured to include front LED covers provided on each of the front sides of the vehicle and one or more rear LED covers provided on the rear of the vehicle, and the transparent micro LED display skin is technically characterized in that it is configured on the outer or inner surface of the front LED cover and the rear LED cover of the vehicle.

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According to the vehicle equipped with self-customizable micro LEDs according to the present invention, the user can easily and continuously change various colors and designs using LEDs according to his/her taste, so that the user can immediately express what he/she wants to express, and the invention is a groundbreaking invention that can enhance the fun of the user through various color and design changes and lead the future design of the exterior of the vehicle using light, and has the effect of allowing long-term use through low-power and rechargeable batteries and its own power supply, and is a useful invention that can replace the effects according to the position and color of each lamp, such as headlamps, position lamps, rear lamps, and reverse lamps, which are used in compartments in conventional vehicles, with a transparent micro LED display skin configured on the front LED cover and the rear LED cover.

Figure 1 is a side view showing a preferred embodiment of the present invention.
Figure 2 is a drawing showing a transparent micro LED display skin among the configurations of the present invention.
Figure 3 is a configuration diagram showing a preferred embodiment of the master part among the configurations of the present invention.
Figure 4 is a configuration diagram showing a preferred embodiment of a remote slave among the configurations of the present invention.
Figure 5 is a side view showing another embodiment of the present invention.
Figure 6 is a side view showing another embodiment of the present invention.

The present invention provides a vehicle equipped with self-customizable micro LEDs, which configures a transparent micro LED display skin on each panel of a vehicle so that a user can easily change the color of each panel configured with a transparent pique LED display skin to improve the beauty of the vehicle's appearance, and which can perform the roles of a headlamp, a position lamp, a rear lamp, and a reverse lamp by using the transparent micro LED display skin configured on the front and rear of the vehicle.

Hereinafter, the preferred configuration and operation of the present invention to achieve the above purpose will be described with reference to FIGS. 1 to 6 with reference to the attached drawings.

First, before explaining the present invention, its configuration will be examined with reference to FIGS. 1 to 4. The present invention comprises: a vehicle (100); a transparent flexible substrate (310) configured on the vehicle (100) and having transparency and flexibility; and a semiconductor device layer (320) having micro LED pixels (330) transferred and attached on the transparent flexible substrate (310), and a transparent micro LED display skin (300) that is completely or partially coated on the surface of the vehicle; A master unit (400) configured on the outside or inside of the vehicle (100), comprising: a power switch (410) for controlling a power supply unit (430); a charging port (420) for charging a battery via a USB cable; a power supply unit (430) controlled by the power switch (410); a battery (440) for storing power charged by the charging port (420); a power wireless supply unit (450) having a wireless electric coil for wirelessly supplying power to the power supply unit (430); a short-range wireless communication unit (460) for short-range wireless communication with external devices including a smartphone (600) and other devices; a main control unit (470) for controlling color expression on a transparent micro LED display skin (300) of the vehicle (100); an energy harvesting unit (480) for self-generating energy; and a light detection unit (490) for detecting the brightness of external light of the vehicle; A remote slave (500) configured to be located at a predetermined distance from the master unit (400) outside or inside the vehicle (100), and which includes a wireless electric antenna (510) for receiving power generated from a power wireless supply unit (450) of the master unit (400), a remote control unit (520) for driving and controlling the transparent micro LED display skin (300), a transmission/reception unit (530) for ultra-close remote transmission/reception with the master unit (400), an energy harvesting unit (540) for self-generating energy, and a light detection unit (550) for detecting the outside and brightness; The above-mentioned master unit (400) and the short-range wireless communication unit (460) and the smart phone (600) including an APP capable of controlling the main control unit (470) or the remote control unit (520) of the master unit (400) or the remote slave (500) through the short-range wireless communication method; the harvesting unit (480, 540) is composed of one or a combination of a photoelectric element, a pressure element, and a wireless electric conversion element, and the transparent micro LED display skin (300) is controlled by the master unit (400) or the remote slave (500) approaching the specific transparent micro LED display skin (300) when the specific transparent micro LED display skin (300) is controlled through the APP, and the micro LED pixel (330) is a compound semiconductor having a band gap as a p-n diode layer, and includes a positive electrode layer (331) that is a circuit pattern, a bump, or a conductive adhesive layer, A vehicle equipped with a self-customized micro LED, wherein a transparent conductive layer (332), a transparent p-electrode layer (333) for power supply, a p-GaN layer (334), an active layer (335), an n-GaN layer (336), and a transparent n-GaN layer (337) having electrical conductivity are sequentially laminated, and a transparent insulating layer (338) is formed between each micro LED pixel (330), wherein the vehicle (100) includes a front bumper panel (110), a bonnet panel (120), a front fender panel (130), a roof panel (140), a door panel (150), a tailgate panel (160), a rear fender panel (170), and a rear bumper panel (180), and the transparent micro LED display skin (300) is formed on the front bumper panel (110), the bonnet panel (120), the front fender panel (130), and the rear bumper panel (180) of the vehicle (100). It is configured on one or more external surfaces of a panel (130), a roof panel (140), a door panel (150), a tailgate panel (160), a rear fender panel (170), and a rear bumper panel (180).

First, the vehicle equipped with the self-customized micro LED of the present invention is composed of a vehicle (100), a transparent micro LED display skin (300), a master unit (400), a remote slave (500), and a smartphone (600).

The present invention, which is configured as described above, will be described in more detail.

First, the vehicle (100) is configured to include a front bumper panel (110), a bonnet panel (120), a front fender panel (130), a roof panel (140), a door panel (150), a tailgate panel (160), a rear fender panel (170), and a rear bumper panel (180).

In addition, the transparent micro LED display skin (300) is configured on one or more external surfaces of the front bumper panel (110), bonnet panel (120), front fender panel (130), roof panel (140), door panel (150), tailgate panel (160), rear fender panel (170), and rear bumper panel (180) of the vehicle (100).

Here, the transparent micro LED display skin (300) may be configured one or more times on the outer surface of the front bumper panel (110), the bonnet panel (120), the front fender panel (130), the roof panel (140), the door panel (150), the tailgate panel (160), the rear fender panel (170), and the rear bumper panel (180), and may be configured to be coated entirely on the outer surface.

That is, the color of each transparent micro LED display skin (300) configured in each of the above panels can be expressed in different colors, so that the user can express it in various colors as desired according to his/her needs, thereby improving the beauty of the vehicle's exterior.

The above transparent micro LED display (300) is 5 to 100 This is a display in which ultra-small LED particles are attached to a substrate (a transparent flexible substrate in the present invention), and it is most suitable for implementing a flexible or roundly bendable screen by utilizing the LED chips themselves as pixels. Compared to OLED, it consumes very little power, so it can be used for a long time, and it can be seen that it is superior to existing OLEDs in terms of illuminance, saturation, and power efficiency.

In addition, when the transparent micro LED display skin (300) is attached to each panel, it is preferable to use a transparent flexible substrate (310) that has both transparency and flexibility so that the vehicle's unique color can be expressed as it is when the transparent micro LED display skin (300) is not used, such as on a clear day or during the day, and to configure the micro LED pixels (330) made of micro LED chips to have maximum transparency.

In addition, the transparent micro LED display skin (300) can be used with various LEDs such as general QLED and OLED.

Meanwhile, a semiconductor device layer (320) having numerous micro LED pixels (330) made of a micro p-n diode layer is formed by transplanting the semiconductor device layer (320) onto a transparent flexible substrate (310) using a micro transfer printing technique, thereby forming a transparent micro LED display skin (300) of the present invention. At this time, when performing the transfer printing technique, it is preferable to use a roll transfer technique so that more than 10,000 micro LED pixels (330) can be transferred and attached to the transparent flexible substrate (310) per second.

Micro LED pixels (330) are prepared on a native substrate and then transferred and printed onto a transparent flexible substrate (310), and the native substrate and unnecessary parts are then removed.

The above transparent flexible substrate (310) is transparent and flexible and has a viscosity of 5 to 10 , 10~50 , 50~100 , 100~200 , 200~500 , one of the thickness ranges of 0.5~1mm, 1~5mm, and 5~10mm is selected.

That is, the transparent micro LED display skin (300) is configured in such a way that a semiconductor device layer (320) having micro LED pixels (330) is attached and formed on a transparent flexible substrate (310) that has both transparency and flexibility.

The micro LED pixel (330) of the semiconductor device layer (320) is configured by sequentially stacking a positive electrode layer (331), a transparent conductive layer (332), a transparent p-electrode layer (333) for power supply, a p-GaN layer (334), an active layer (335), an n-GaN layer (336), and a transparent n-GaN layer (337) having electrical conductivity, and a transparent insulating layer (338) is formed between each micro LED pixel (330).

Each of the micro LED pixels (330) formed on the semiconductor device layer (320) is a p-n diode layer and is composed of a compound semiconductor having a band gap corresponding to a specific region within the spectrum, and is formed of, for example, gallium nitride (GaN), a group III to V nitride material.

The above transparent p-electrode layer is formed of an electrode made of an oxide containing Al, Ga, Ag, Sn, In, Zn, Co, Ni, or Au having a transmittance of 70% or more for power supply, and the positive electrode layer (331) can be selected from the group consisting of silver and nickel having reflectivity for the visible spectrum, and forms a potential reflective mirror layer.

In addition, the present invention can implement a transparent micro LED display skin (300) in various colors by arranging three elements, i.e., micro LED panels, having red, green, and blue colors.

In other words, the present invention enables the color and design of a general vehicle (100) to be expressed when the transparent micro LED display skin (300) of the vehicle (100) is not in operation, and enables various colors to be output to the outside when the transparent micro LED display skin (300) is in operation.

Here, the transparent micro LED display skin (300) is controlled by a master unit (400) or remote slave (500) approaching the specific transparent micro LED display skin (300) when the specific transparent micro LED display skin (300) is controlled through the APP.

In addition, the transparent micro LED display skin (300) is configured as the entire or partial outer surface of each panel of the vehicle (100), so as to enable various colors and designs to be expressed on the outer surface of the vehicle (100) according to the control of the smartphone (600) described below.

Meanwhile, the master unit (400) is configured on the outside or inside of the vehicle (100) as shown in FIG. 4, and includes a power switch (410) for controlling the power supply unit (430), a charging port (420) for charging the battery via a USB cable, a power supply unit (430) controlled by the power switch (410), a battery (440) for storing power charged by the charging port (420), a power wireless supply unit (450) having a wireless electric coil for wirelessly supplying power to the power supply unit (430), a short-range wireless communication unit (460) for short-range wireless communication with external devices including a smartphone (600) and other devices, a main control unit (470) for controlling color expression in the transparent micro LED display skin (300), an energy harvesting unit (480) for self-generating energy, and a power supply unit for detecting the brightness of external light of the vehicle. It consists of a light detection unit (490).

It is preferable that the IC chip of the main control unit (470) built into the exterior side or interior side of the vehicle (100) be implemented as an application specific integrated circuit (ASIC), and the wireless power and energy harvesting unit (480) can supply energy by applying a solar cell.

Meanwhile, a remote slave (500) for wirelessly receiving power supplied from a master unit (400) configured in the vehicle (100) is configured at a position spaced apart from the master unit (400) of the vehicle (100), and includes a wireless electric antenna (510) for receiving power generated from the power wireless supply unit (450), a remote control unit (520) in the form of an IC chip for driving and controlling the transparent micro LED display skin (300), a transmission/reception unit (530) for ultra-close remote transmission/reception with the master unit (400), an energy harvesting unit (540) for self-generation of energy, and a light detection unit (550) for detecting the exterior and brightness of the vehicle.

The IC (Integrated Circuit) of the above remote control unit (520) can form a micron-scale direct circuit using a complementary metal oxide semiconductor (CMOS), and the IC chip has an area of 1 mm x 1 mm and a thickness of 0.5 mm is preferable.

Meanwhile, power generated through a resonance phenomenon in the wireless electric coil of the power wireless supply unit (450) configured in the vehicle (100) of the present invention is received by the wireless electric antenna (510) of the remote slave (500), and the received power is used to drive the transparent micro LED display skin (300) through the control of the remote control unit (520).

The above harvesting unit (480, 540) is a means of harvesting energy from the surroundings, and generates power and supplies it to each internal part without receiving a separate battery power supply. It is preferable that it be composed of one or a combination of a photoelectric element, a thermoelectric element, a pressure element, and a wireless electric conversion element. The light detection unit (490, 550) detects the amount of external light applied to the vehicle and then applies it to the main control unit (470) and the remote control unit (520), respectively. The main control unit (470) and the remote control unit (520) control the display brightness of the transparent micro LED display skin (300) based on the amount of light applied.

In addition, the system further includes a smartphone (600) including an APP that can control the main control unit (470) or remote control unit (520) of the master unit (400) or remote slave (500) through a short-range wireless communication method, the short-range wireless communication unit (460), and the master unit (400).

The wireless transmission/reception method between the above master unit (400) and the smartphone (600) can utilize Li-Fi technology that implements a high communication speed by utilizing the wavelength of light emitted from an LED, and in particular, if the micro LED technology of the present invention is applied, the effect of reducing the weight of the component can be increased.

That is, the smartphone (600) can control design and color changes through short-range remote control between the vehicle (100) and the smartphone (600), and the master unit (400) can wirelessly connect to the smartphone (600) using a short-range wireless communication method such as Bluetooth communication, Wi-Fi communication, NFC communication, IR communication, and Li-Fi communication, and when users selectively control the APP included in the smartphone (600), various colors and designs can be expressed on the transparent micro LED display skin (300) according to the control command.

In addition, when operating the transparent micro LED display skin (300) with the APP of the smartphone (600) that controls the master unit (400) and remote slave (500) of the present invention, when the first control command is transmitted to the master unit (400), the master unit (400) operates the transparent micro LED display skin (300), but when the distance between the master unit (400) and a specific transparent micro LED display skin (300) is far, the control command is transmitted to the remote slave (500), and the remote slave (500) operates the corresponding transparent micro LED display skin (300).

That is, when a specific transparent micro LED display skin (300) is operated with the first smartphone (600), a master unit (400) or a remote slave unit (500) that is close to the specific transparent micro LED display skin (300) operates the specific transparent micro LED display skin (300), thereby providing the advantage of fast and accurate control.

Meanwhile, a transparent micro LED display skin (300) is formed on the outer surface of the front bumper panel (110), the bonnet panel (120), the front fender panel (130), the roof panel (140), the door panel (150), the tailgate panel (160), the rear fender panel (170), and the rear bumper panel (180) of the vehicle (100), a master unit (400) is formed on one or more of the panels, and a remote slave (500) is formed on the remaining panels, so that the master unit (400) controls the transparent micro LED display skin (300) of the panel on which the master unit (400) is formed, and the remote slave (500) controls the transparent micro LED display skin (300) of the panel on which the remote slave (500) is formed, according to a signal transmitted from a smartphone (600).

At this time, the remote slave (500) does not receive a direct signal from the smartphone (600), but receives the signal from the master unit (400).

That is, the present invention configures a transparent micro LED display skin (300) on a panel of a vehicle (100) including a plurality of panels, and then configures a master unit (400) and a remote slave (500) respectively so that the transparent micro LED display skin (300) can be controlled by the master unit (400) or the remote slave (500) located at a close distance, and configures a transparent micro LED display skin (300) on each of a plurality of panels, configures a master unit (400) on one or more of the panels, and configures a remote slave (500) on the remaining panels so that it can be used.

In addition, the vehicle (100) is configured to include a front LED cover (193) provided on each of the front sides of the vehicle (100) and a rear LED cover (195) provided one or more at the rear of the vehicle (100), and the transparent micro LED display skin (300) is configured on the outer or inner surface of the front LED cover (193) and the rear LED cover (195) of the vehicle (100).

That is, by configuring the transparent micro LED display skin (300) on the outer or inner surface of the front LED cover (193) and the rear LED cover (195), the roles of conventional headlamps, position lamps (daylights), rear lamps, reverse lamps, etc. are replaced by the transparent micro LED display skin (300), so that the roles of each lamp can be performed.

Meanwhile, a plurality of grooves (h) are formed by insertion in the front bumper panel (110), bonnet panel (120), front fender panel (130), roof panel (140), door panel (150), tailgate panel (160), rear fender panel (170), and rear bumper panel (180) of the vehicle (100), and the transparent micro LED display skin (300) is configured in each of the grooves (h).

That is, since the transparent micro LED display skin (300) is configured to be inserted into the home portion (h), when the transparent micro LED display skin (300) is not used, such as on a clear day or during the day, it can be prevented from protruding out of the vehicle and deteriorating the vehicle's existing appearance, and can be minimized from being damaged or broken by other external factors.

Here, the groove portion (h) may be formed in a plurality of groove portions (h) in each of the front bumper panel (110), the bonnet panel (120), the front fender panel (130), the roof panel (140), the door panel (150), the tailgate panel (160), the rear fender panel (170), and the rear bumper panel (180) of the vehicle (100), and in the present invention, a plurality of groove portions (h) are formed in the front fender panel (130), the door panel (150), and the rear fender panel (170), and a transparent micro LED display skin (300) is inserted into each of the groove portions (h).

In addition, as shown in Fig. 6, the door panel (150) is preferably formed with a plurality of grooves (h) spaced apart from each other at equal intervals in the upper and lower directions, with the upper and lower widths becoming narrower as they go downward.

First, it is preferable that the transparent micro LED display skin (300) is configured to be interpolated in a size corresponding to the size of each of the above-mentioned home portions (h).

That is, a plurality of grooves (h) are formed at equal intervals from top to bottom on the door panel (150), and the width from top to bottom gradually narrows as it goes downward, so that a transparent micro LED display skin (300) is placed on the lower part of the door panel (150) where exposure is relatively small, minimizing the size used and reducing the overall cost.

Here, at least two or more grooves (h) are formed in the door panel (150) above with a certain interval between them in the upper and lower directions, and the upper and lower width of the groove (h) located at the lower side of each groove (h) is formed to be 80% of the upper and lower width of the groove (h) located at the upper side thereof.

According to the vehicle equipped with self-customizable micro LEDs according to the present invention, the user can easily and continuously change various colors and designs using LEDs according to his/her taste, so that the user can immediately express what he/she wants to express, and the invention is a groundbreaking invention that can enhance the fun of the user through various color and design changes and lead the future design of the exterior of the vehicle using light, and has the effect of allowing long-term use through low-power and rechargeable batteries and its own power supply, and is a useful invention that can replace the effects according to the position and color of each lamp, such as headlamps, position lamps, rear lamps, and reverse lamps, which are used in compartments in conventional vehicles, with a transparent micro LED display skin configured on the front LED cover and the rear LED cover.

100 : Vehicle
110 : Front bumper panel 120 : Bonnet panel
130 : Front fender panel 140 : Roof panel
150 : Door panel 160 : Tailgate panel
170: Rear fender panel 180: Ripper bumper panel
193: Front LED cover 195: Rear LED cover
300 : Transparent Micro LED Display Skin
310: Transparent flexible substrate 320: Semiconductor device layer
330 : Micro LED pixels
331: Positive electrode layer 332: Transparent conductive layer
333: Transparent p-electrode layer 334: p-GaN layer
335: Active layer 336: n-GaN
337: Transparent n-GaN layer 338: Transparent insulating layer
400 : Master Department
410: Power switch 420: Charging port
430: Power supply 440: Battery
450: Power wireless supply unit 460: Short-range wireless communication unit
470: Main control unit 480: Harvesting unit
490 : Photodetector
500 : Remote Slave
510: Wireless electric antenna 520: Remote control unit
530: Transmitter/Receiver 540: Harvesting Unit
550 : Photodetector
600 : Smartphone
h : home

Claims (4)

Vehicle (100);
A transparent flexible substrate (310) configured in the vehicle (100) and having transparency and flexibility, and a semiconductor device layer (320) having micro LED pixels (330) are transferred and attached on the transparent flexible substrate (310) to form a transparent micro LED display skin (300) that is completely or partially applied to the surface of the vehicle;
A master unit (400) configured on the outside or inside of the vehicle (100), comprising: a power switch (410) for controlling a power supply unit (430); a charging port (420) for charging a battery via a USB cable; a power supply unit (430) controlled by the power switch (410); a battery (440) for storing power charged by the charging port (420); a power wireless supply unit (450) having a wireless electric coil for wirelessly supplying power to the power supply unit (430); a short-range wireless communication unit (460) for short-range wireless communication with external devices including a smartphone (600) and other devices; a main control unit (470) for controlling color expression on a transparent micro LED display skin (300) of the vehicle (100); an energy harvesting unit (480) for self-generating energy; and a light detection unit (490) for detecting the brightness of external light of the vehicle;
A remote slave (500) configured to be located at a predetermined distance from the master unit (400) outside or inside the vehicle (100), and which includes a wireless electric antenna (510) for receiving power generated from a power wireless supply unit (450) of the master unit (400), a remote control unit (520) for driving and controlling the transparent micro LED display skin (300), a transmission/reception unit (530) for ultra-close remote transmission/reception with the master unit (400), an energy harvesting unit (540) for self-generating energy, and a light detection unit (550) for detecting the outside and brightness;
It consists of a smartphone (600) including an APP that can control the main control unit (470) or remote control unit (520) of the master unit (400) or remote slave (500) through the above-mentioned master unit (400) and the short-range wireless communication unit (460) and the short-range wireless communication method;
The above harvesting unit (480, 540) is composed of one or a combination of a photoelectric element, a piezoelectric element, and a wireless electric conversion element.
The above transparent micro LED display skin (300) is controlled by a master unit (400) or remote slave (500) approaching the specific transparent micro LED display skin (300) when the specific transparent micro LED display skin (300) is controlled through the APP.
The above micro LED pixel (330) is a compound semiconductor having a band gap as a pn diode layer, and is configured by sequentially stacking a positive electrode layer (331) that serves as a circuit pattern or bump or a conductive adhesive layer, a transparent conductive layer (332), a transparent p-electrode layer (333) for power supply, a p-GaN layer (334), an active layer (335), an n-GaN layer (336), and a transparent n-GaN layer (337) having electrical conductivity, and a vehicle equipped with a self-customized micro LED, wherein a transparent insulating layer (338) is formed between each micro LED pixel (330).
The above vehicle (100) is configured to include a front bumper panel (110), a bonnet panel (120), a front fender panel (130), a roof panel (140), a door panel (150), a tailgate panel (160), a rear fender panel (170), and a rear bumper panel (180).
The above transparent micro LED display skin (300) is configured on the outer surface of each of the front bumper panel (110), bonnet panel (120), front fender panel (130), roof panel (140), door panel (150), tailgate panel (160), rear fender panel (170), and rear bumper panel (180) of the vehicle (100).
A plurality of grooves (h) are formed by inserting them into the front bumper panel (110), bonnet panel (120), front fender panel (130), roof panel (140), door panel (150), tailgate panel (160), rear fender panel (170), and rear bumper panel (180) of the above vehicle (100).
The above transparent micro LED display skin (300) is configured in each of the above home portions (h),
In the above door panel (150), a number of grooves (h) are formed by inserting each groove at a certain interval from top to bottom, and the width from top to bottom becomes narrower as it goes toward the bottom.
A vehicle equipped with a self-customizable micro LED, characterized in that the vertical width of the groove (h) located at the bottom of each groove (h) formed on the door panel (150) is formed to be 80% of the vertical width of the groove (h) located at the top thereof.
In paragraph 1,
The above vehicle (100) is configured to include a front LED cover (193) provided on each of the front sides of the vehicle (100) and a rear LED cover (195) provided in one or more numbers at the rear of the vehicle (100).
A vehicle equipped with self-customized micro LEDs, characterized in that the transparent micro LED display skin (300) is configured on the outer or inner surface of the front LED cover (193) and the rear LED cover (195) of the vehicle (100).
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