CN109386099B - Intelligent 3D color-changing brick - Google Patents

Abstract

The invention discloses an intelligent 3D color-changing brick. The intelligent 3D color-changing brick comprises an optical glass plate, a light guide material plate and a cement net which are sequentially connected, wherein a pattern layer is arranged on one surface, close to the light guide material plate, of the optical glass plate, a plurality of optical salient points protruding towards the direction far away from the optical glass plate are arranged on one surface, far away from the light guide material plate, of the optical glass plate, a light source accommodating groove is formed in the light guide material plate, and a lamp body is hermetically installed in the light source accommodating groove; the lamp body is electrically connected with an intelligent controller through a connecting wire. The intelligent 3D color-changing brick can realize non-distance control of pattern color, solves the problem of control and adjustment at any place and any time, and brings convenience to users; the product adopts a composite structure of glass and a light source, has small thickness and light weight, and is convenient to transport; the glass is provided with the salient points, the salient points and the pattern layer form a 3D (three-dimensional) effect correspondingly, and the wear-resistant and anti-skid effects are realized; the whole product has no frame and support and is convenient to install.

Description

Intelligent 3D color-changing brick

Technical Field

The invention relates to the technical field of color bricks, in particular to an intelligent 3D color-changing brick.

Background

The color-changing tile is a glass tile developed by mobile color companies, and is most suitable for being used in bathrooms and kitchens with large indoor temperature change because the appearance color of the color-changing tile changes along with the temperature. In addition to this, the use of such heat-sensitive tiles can present the artistic effect of walls or floors, and even as a creative element of children's books.

The prior color-changing brick generally arranges a pattern at the bottom of a floor, and a frame is adopted at the periphery to enclose the floor, so that the floor is convenient to mount; the patterns are fixed, and different patterns are adopted in different places, and the colors of the patterns can change along with the change of temperature. The color of the color-changing brick is preset, the color can not be changed at any time according to the scene requirement, and the color-changing brick is inconvenient to use; the pattern is a plane pattern, and has no three-dimensional effect, so that the requirements of some users cannot be met; the installation is carried out through a bracket or a frame, the installation is inconvenient, the cost is high, and the visual effect is not good; the product is large in thickness and inconvenient to transport; the anti-slip effect is poor.

Disclosure of Invention

Based on the intelligent 3D color-changing brick, the intelligent controller can be controlled through the APP, the switch and the like, the color gray scale of the brick can be adjusted without distance limitation, the pattern color can be controlled according to different use scenes, the problem of control and adjustment at any place and any time is solved, and convenience is brought to a user; the product adopts a composite structure of glass and a light source, has small thickness and light weight, and is convenient to transport; the glass is provided with the salient points, the salient points and the pattern layer form a 3D (three-dimensional) effect correspondingly, and the wear-resistant and anti-skid effects are realized; the whole product has no frame and support, convenient installation and low cost.

In order to realize the purpose of the invention, the invention adopts the following technical scheme:

an intelligent 3D color-changing brick comprises an optical glass plate, a light guide material plate and a cement net which are sequentially connected, wherein a pattern layer is arranged on one surface, close to the light guide material plate, of the optical glass plate, a plurality of optical salient points protruding towards the direction far away from the optical glass plate are arranged on one surface, far away from the light guide material plate, of the optical glass plate, a light source accommodating groove is formed in the light guide material plate, and a lamp body is hermetically installed in the light source accommodating groove; the lamp body is electrically connected with an intelligent controller through a connecting wire.

The intelligent 3D color-changing brick can control the intelligent controller through the APP, the switch and the like, realize the adjustment of the color gray scale without distance limitation, control the pattern color according to different use scenes, solve the problem of control and adjustment at any place and any time, and bring convenience to users; the product adopts a composite structure of glass and a light source, has small thickness and light weight, and is convenient to transport; the glass is provided with the salient points, the salient points and the pattern layer form a 3D (three-dimensional) effect correspondingly, and the wear-resistant and anti-skid effects are realized; the whole product has no frame and support, convenient installation and low cost.

In some embodiments, the intelligent controller is connected with the APP through WiFi or bluetooth, and the APP is used for controlling the lamp body. Remote control can be realized through APP, and the use is more convenient.

In some embodiments, the pattern layer is compounded on one side of the optical glass plate close to the light guide material plate by means of printing.

In some embodiments, the number of the light source accommodating grooves is two, the two light source accommodating grooves are respectively arranged at the positions close to the two opposite sides of the light guide material plate, and the lamp body is sealed in the light source accommodating grooves through the heat conduction silica gel. Therefore, the lamp body achieves the waterproof and dustproof functions.

In some embodiments, the light source accommodating groove is formed in a surface of the light guide material plate away from the optical glass plate.

In some embodiments, a floodlight panel is further disposed between the light guide material plate and the cement mesh.

In some embodiments, the intelligent controller comprises a control unit and an LED driving unit, the control unit is a full-color LED driving chip with a gray scale generator, the control unit receives an instruction sent by an APP and sends a control signal and data to the LED driving unit through an internal control program, and the LED driving unit controls R, G, B lighting gray scale of the lamp body.

In some embodiments, the LED driving unit includes a plurality of LED driving chips, the number of the LED driving chips corresponds to the number of the lamp bodies, and the intelligent controller continuously sends control signals and data to the plurality of LED driving chips, so that each of the lamp bodies is continuously and coordinately controlled.

In some embodiments, the control unit converts a data format and a suitable control instruction which can be processed by the control unit into a data format and a suitable control instruction in advance according to an expected change effect, and stores the data format and the suitable control instruction, so that the control unit sends a signal to each LED driving chip, and the intelligent 3D color-changing brick can show a required effect.

In some embodiments, the optical bump has a circular arc shape, wherein the circular arc portion is focused on the pattern layer.

Drawings

Fig. 1 is a schematic structural diagram of an intelligent 3D color-changing brick according to a preferred embodiment of the present invention;

FIG. 2 is a schematic diagram of an intelligent controller of the intelligent 3D color-changing brick according to a preferred embodiment of the invention;

fig. 3 is a schematic structural diagram of an LED driving unit of the controller shown in fig. 2.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

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

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

Examples

Referring to fig. 1, the intelligent 3D color-changing brick 100 according to the present invention includes an optical glass plate 10, a light guide material plate 20 and a cement mesh 40, which are connected in sequence, wherein a pattern layer 11 is disposed on a surface of the optical glass plate 10 close to the light guide material plate 20, an optical bump 12 is disposed on a surface of the optical glass plate 10 away from the light guide material plate 20, the optical bump 12 protrudes in a direction away from the optical glass plate 10, a light source accommodating groove 21 is disposed on the light guide material plate 20, a lamp body is hermetically mounted in the light source accommodating groove 21, and the lamp body is electrically connected to an intelligent controller 60 through a connection line 50.

Above-mentioned intelligence 3D brick 100 that discolours, accessible APP, control intelligent control ware such as switch realize having no distance restriction to adjust its colour grey scale, come control pattern colour according to the use scene of difference, solve the arbitrary place arbitrary time control regulation, bring the convenience for the user. Moreover, the product adopts a composite structure of glass and a light source, has small thickness and light weight and is convenient to transport; the glass is provided with the salient points, the salient points and the pattern layer form a 3D (three-dimensional) effect correspondingly, and the wear-resistant and anti-skid effects are realized; the whole product has no frame and support, convenient installation and low cost.

In one embodiment, the optical glass plate 10 is formed by firing tempered glass at a high temperature, and the optical bump 12 is formed on one surface of the optical glass plate 10. The optical bumps 12 are in the shape of circular arcs, protrude in the direction away from the optical glass plate 10, and are focused on the pattern layer 11 behind the optical glass plate 10. The height of the optical bumps 12 is similar to the lens of a camera, the height, density and size of the optical bumps correspond to the pattern of the pattern layer 11 and the effect to be achieved, the height must be accurate, otherwise the pattern is blurred if not focused. The optical bumps 12 themselves have abrasion-resistant and anti-slip functions. After the optical salient points 12 are designed, the corresponding pattern layers, namely 3D patterns, are manufactured aiming at the optical salient points 12, so that the product has not only a 3D effect, but also a three-dimensional layering sense or a dynamic sense, namely a naked eye 3D effect.

Specifically, according to the arrangement rule of the optical bumps 12, a corresponding pattern is generated by using computer software, and the three-dimensional depth of the pattern needs to be accurately calculated, for example, in an array arrangement. The field depth range is measured and calculated, the design is carried out in the range, the pattern is blurred when the range is exceeded, and the size of the field depth range is closely related to the output equipment. The higher the output accuracy, the larger the depth of field can be. The visual effect of the physical map is arranged according to the layout of the whole picture. And controlling the shaking amplitude of the picture to be stable as much as possible. The comfort level of the picture determines the visual experience effect. The foreground and background proportion is reasonably distributed, and the depth of field is reasonably and fully utilized.

The specific manufacturing method of the pattern layer 11 comprises the following steps: after the pattern is designed, the pattern is printed on paper by an ink jet printer and attached to one surface of the optical glass plate 10 to form a pattern layer 11. Or directly outputting the optical glass plate 10 to one side by using a UV printer, namely directly compounding the pattern layer 11 on the optical glass plate 10. If the pattern is a monochromatic pattern, the pattern can be directly printed by a screen printer.

The different styles and styles of the pattern layers can be customized personally.

Light guide material board 20 is made by the light guide material of 8mm thick, and the one side of keeping away from optical glass board 10 at light guide material board 20 is close to the edge and sets up two light source storage tanks 21 relatively, installs the lamp body in light source storage tank 21, then seals completely with filling heat conduction silica gel, and external waterproof engineering plug cord, connecting wire 50 promptly connects 12V operating voltage. The light source accommodating groove 21 is 5mm deep and 4mm wide, and the light source accommodating groove 21 is not completely penetrated, i.e., the depth of the light source accommodating groove 21 is smaller than the thickness of the light guide material plate 20. The lamp body achieves waterproof and dustproof functions and can be electrically connected with an external intelligent controller 60. The light guide material plate 20 is combined and connected with the optical glass plate 10 by means of adhesion. The number of the light source accommodating grooves 21 is two, the two light source accommodating grooves are respectively arranged at two opposite sides close to the light guide material plate 20, and the lamp body is sealed in the light source accommodating grooves 21 through the heat conduction silica gel. The lamp body achieves the waterproof and dustproof functions, can be applied outdoors, and thoroughly solves the water leakage safety problem. The light source accommodating groove 21 is opened on a surface of the light guide material plate 20 away from the optical glass plate 10.

The lamp body is an LED lamp body which comprises three colors of R (red), G (green) and B (blue).

In one embodiment, the light guide material plate 20 is a light guide plate. In other embodiments, the light guide material plate 20 is made of light-transmissive material such as acrylic plate, glass plate, PS plate, etc.

Further, a floodlight board 30 is arranged between the light guide material board 20 and the cement net 40, and the floodlight board 30 is bonded between the light guide material board 20 and the cement net 40 in a bonding mode. Used for diffusing the light emitted by the lamp bodies on both sides of the light guide material plate 20 to the whole plate body.

In one embodiment, the cement mesh 40 is adhesively attached to the side of the floodlight panel 30 remote from the light guiding material sheet 20. The cement net 40 can be directly connected with the ground, so that a frame or a support is omitted, the whole product has no frame or support, the installation is convenient, and the cost is low.

Referring to fig. 2 and 3, in an embodiment, the intelligent controller is connected to the APP via WiFi or bluetooth. The intelligent controller comprises a control unit and an LED driving unit, the control unit is a full-color LED driving chip with a gray scale generator, the control unit receives an instruction sent by an APP, and sends a control signal and data to the LED driving unit through an internal control program, and the LED driving unit controls R, G, B light-emitting gray scale of the lamp body. Because the LED lamp body has the light-emitting characteristic, the LED lamp body has the characteristics of easy control and quick stroboflash, and therefore the R (red), G (green) and B (blue) luminous gray scales can be independently controlled by utilizing the embedded microprocessor according to a PWM (duty ratio) mode, and the LED light control technology with a full-color effect is realized. The control unit is a lamp unit capable of independently changing full color, which may also be referred to as a pixel, and is typically a DM413 of taiwan point crystal technology (the core recipe scheme may be different chip recipes according to actual applications).

Further, the LED driving unit comprises a plurality of LED driving chips, the number of the LED driving chips corresponds to the number of the lamp bodies, the LED driving chips are full-color LED driving chips and are provided with gray level generators, 256 gray levels are defaulted, the highest gray level can be set to 8192 gray levels, and the achieved effect is extremely fine and smooth. The intelligent controller continuously sends control signals and data to the LED driving chips so that the lamp bodies are continuously and coordinately controlled. The control unit converts the expected change effect into a data format which can be processed by the control unit and a proper control instruction in advance for storage, so that the control unit sends signals to each LED driving chip to enable the intelligent 3D color-changing brick to show the required effect. Wherein, a single DM413 chip only controls one LED driving unit, so that the circuit of each control unit is the same, and the control unit is very simple, once developed and repeatedly used.

In other embodiments, the intelligent controller is connected to the intelligent switch, and the intelligent switch includes various modes such as wireless, touch, wired and the like.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (8)

1. An intelligent 3D color-changing brick is characterized by comprising an optical glass plate, a light guide material plate and a cement net which are sequentially connected, wherein a pattern layer is arranged on one surface, close to the light guide material plate, of the optical glass plate, a plurality of optical convex points protruding towards the direction far away from the optical glass plate are arranged on one surface, far away from the light guide material plate, of the optical glass plate, the optical convex points are arc-shaped, the arc parts of the optical convex points are focused on the pattern layer, a light source accommodating groove is formed in the light guide material plate, the light source accommodating groove is formed in the surface, far away from the optical glass plate, of the light guide material plate, and a lamp body is hermetically installed in the; the lamp body is electrically connected with an intelligent controller through a connecting wire; a floodlight board is arranged between the light guide material board and the cement net; the cement net is connected with one surface, far away from the light guide material plate, of the floodlight plate in a bonding mode.

2. The intelligent 3D color changing tile of claim 1, wherein: the intelligent control ware passes through wiFi or the bluetooth is connected with APP, APP is used for control the lamp body.

3. The intelligent 3D color changing tile of claim 1, wherein: the pattern layer is compounded on one surface, close to the light guide material plate, of the optical glass plate in a printing mode.

4. The intelligent 3D color changing tile of claim 1, wherein: the number of the light source accommodating grooves is two, and the two light source accommodating grooves are respectively arranged at the positions close to the two opposite sides of the light guide material plate; the lamp body is sealed in the light source accommodating groove through the heat conduction silica gel.

5. The intelligent 3D color-changing tile of claim 4, wherein: the lamp body is an LED lamp body.

6. The intelligent 3D color changing tile of claim 1, wherein: the intelligent control ware includes the control unit and LED drive unit, the full-color LED driver chip of control unit for having grey level generator, the control unit receives the instruction that APP sent to through internal control procedure to LED drive unit sends control signal and data, LED drive unit control the R, G, B luminous grey scale of lamp body.

7. The intelligent 3D color-changing tile of claim 6, wherein: the LED driving unit comprises a plurality of LED driving chips, the number of the LED driving chips corresponds to that of the lamp bodies, and the intelligent controller continuously sends control signals and data to the LED driving chips so that the lamp bodies are continuously and coordinately controlled.

8. The intelligent 3D color changing tile of claim 7, wherein: the control unit converts a data format which can be processed by the control unit and a proper control instruction into a data format which can be processed by the control unit according to an expected change effect in advance and stores the data format and the proper control instruction, so that the control unit sends a signal to each LED driving chip to enable the intelligent 3D color-changing brick to show a required effect.

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