CN111765441A - Light guide lighting hollow glass brick for indoor design and glass wall - Google Patents

Abstract

The invention discloses a light guide lighting hollow glass brick and glass wall for indoor design, the glass brick comprises: the glass brick body consists of an inner brick body and an outer brick body which are mutually butted, a containing groove is formed in the bottom of the glass brick body, a socket is formed in the bottom of the containing groove, a first limiting convex edge is arranged on the inner wall of the inner brick body, and a second limiting convex edge is arranged on the inner wall of the outer brick body; the light guide plate is fixed inside the glass brick body, is limited by the first limiting convex edge and the second limiting convex edge, and extends into the accommodating groove through the socket; and the light emitting piece comprises a light source plate inserted into the accommodating groove and a light source for illuminating the light guide plate. By adopting the scheme of the invention, the light effect requirement of the glass brick can be realized, the dismounting and replacement requirements of the luminous element can be realized, and the practicability of the light guide lighting hollow glass brick is improved; but also can reduce the cost and simplify the manufacturing process.

Description

Light guide lighting hollow glass brick for indoor design and glass wall

Technical Field

The invention relates to the technical field of indoor design, in particular to a light guide lighting hollow glass brick and a glass wall for indoor design.

Background

The glass brick with the lighting function can realize colorful illumination effect, and is widely applied to various scenes. The existing glass brick with the illumination function needs to embed a light source into the glass brick, so that the cost is high and the manufacturing process is complicated. Moreover, after the glass brick is fixed on a wall body by glue or other bonding agents, the light source cannot be replaced, and once the light source is damaged, the glass brick does not have the lighting effect, so that the using effect of the glass brick is greatly reduced, and the practicability is poor. Therefore, the glass brick with the lighting function cannot be accepted by the market.

Disclosure of Invention

The invention discloses a light guide lighting hollow glass brick for indoor design and a glass wall, which are used for solving the problem that in the prior art, a light source in the glass brick cannot be replaced and maintained after being damaged.

In order to solve the problems, the invention adopts the following technical scheme:

there is provided a light guide lighting hollow glass block for interior design, comprising:

the glass brick comprises a glass brick body, wherein the glass brick body is composed of an inner side brick body and an outer side brick body which are mutually butted, a containing groove extending along the butted surface of the inner side brick body and the outer side brick body is arranged at the bottom of the glass brick body, two ends of the containing groove penetrate through the glass brick body, a socket communicated with the inside of the glass brick body is arranged at the bottom of the containing groove, a first limiting convex edge which is positioned on one side of the socket and extends along the circumferential direction of the butted surface is arranged on the inner wall of the inner side brick body, and a second limiting convex edge which is positioned on the other side of the socket and extends along the circumferential direction of the butted surface is arranged on the inner wall;

the light guide plate is fixed inside the glass brick body, is limited by the first limiting convex edge and the second limiting convex edge, and extends into the accommodating groove through the socket;

the light emitting piece comprises a light source plate and a light source, wherein one end of the accommodating groove is inserted into the accommodating groove, and the light source is fixed on the light source plate to illuminate the light guide plate.

Optionally, at least two layers of the light guide plates are arranged between the first limiting convex edge and the second limiting convex edge, the adjacent two layers of the light guide plates are fixed at intervals through a shading isolation rubber frame, a plurality of reference light guide bubbles illuminated by the light source are distributed on the reference light guide plate positioned on the inner side, the rest of the matched light guide plates are provided with matched light guide bubbles which correspond to the reference light guide bubbles and are sequentially staggered from inside to outside, and the shading isolation rubber frame is abutted against the light source plate and the glass brick body;

the light emitting member includes light sources respectively corresponding to the reference light guide plate and the mating light guide plate, and the light sources alternately emit light in sequence.

Optionally, the light guide plate is provided with two layers, and each reference light guide bubble and the corresponding matching light guide bubble form a starry sky light effect; or

The light guide plate is provided with three layers, and each reference light guide bubble and the corresponding matched light guide bubble form a meteor light effect.

Optionally, when the reference light guide bubbles and the matching light guide bubbles form a starry sky light effect, the diameters of the reference light guide bubbles and the matching light guide bubbles are both less than 0.5mm and parallel to the direction of the reference light guide plate, and the distance between the reference light guide bubbles and the corresponding matching light guide bubbles is less than 0.1 mm;

when the reference light guide bubbles and the rest of the matching light guide bubbles form a meteor light effect, the diameters of the reference light guide bubbles and the matching light guide bubbles are between 0.5mm and 1mm and are parallel to the direction of the reference light guide plate, the distance between the reference light guide bubbles and the matching light guide bubbles corresponding to the middle is 0.3 mm to 0.5mm, and the distance between the matching light guide bubbles corresponding to the middle and the outer sides is 0.5mm to 0.8 mm.

Optionally, the light guide plate is provided with a layer, and the light guide plate is a semitransparent or frosted light homogenizing plate.

Optionally, a groove is formed in the top of the light source plate, and the light source is arranged at the bottom of the groove and faces the light guide plate.

Optionally, along the butt joint face direction of the inner side brick body and the outer side brick body, the light source plate is sequentially provided with a plurality of grooves at intervals, each groove is provided with the light source, and different light sources in the grooves illuminate different light guide plates in the glass brick body.

Optionally, the orientation of light source board the lateral surface of the outside brick body is equipped with first light guide board, the top of light source board be equipped with first light guide board is connected and is extended to second light guide board in the recess, first light guide board is the one deck and is equipped with and assists the leaded light bubble, second light guide board presents even illuminating effect, and follows the lateral surface of light source board extremely the recess direction, the second light guide board orientation the bottom slope of light source board.

Optionally, the first limiting convex edge is positioned on the top wall and the side wall of the inner brick body;

the second limiting convex edge is positioned on the top wall and the side wall of the outer side brick body.

The glass wall comprises light guide illumination hollow glass bricks which are arranged in a matrix, wherein the light guide illumination hollow glass bricks are the light guide illumination hollow glass bricks in any one of the above items.

The technical scheme adopted by the invention can achieve the following beneficial effects:

by arranging the light guide plate, the light effect requirement of the glass brick can be met, the dismounting and replacement requirements of the light-emitting piece can be met, and the practicability of the light guide lighting hollow glass brick is improved; but also can reduce the cost and simplify the manufacturing process.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below to form a part of the present invention, and the exemplary embodiments and the description thereof illustrate the present invention and do not constitute a limitation of the present invention. In the drawings:

FIG. 1 is a schematic perspective view of a light guide illumination hollow glass block according to an embodiment of the present invention;

FIG. 2 is a schematic view of the internal structure of a light guide illumination hollow glass block disclosed in the embodiment of the present invention;

FIG. 3 is a schematic front view of an inner brick according to an embodiment of the present invention;

fig. 4 is a schematic view of an arrangement structure of a three-layer light guide plate according to an embodiment of the disclosure;

FIG. 5 is a schematic diagram illustrating an arrangement structure of light guide bubble groups in a two-layer light guide plate according to an embodiment of the present invention;

FIG. 6 is a schematic diagram illustrating an arrangement structure of light guide bubble groups in a three-layered light guide plate according to an embodiment of the present invention;

FIG. 7 is a schematic structural diagram of a light emitting device with a light guide plate according to an embodiment of the present invention;

FIG. 8 is a schematic structural view of a light emitting device with three light guide plates according to an embodiment of the present invention;

FIG. 9 is a schematic side view of a glass wall according to an embodiment of the present invention;

fig. 10 is a schematic front structural view of a glass wall according to an embodiment of the present invention.

Wherein the following reference numerals are specifically included in figures 1-10:

a glass brick body-1; a light guide plate-2; a light emitting member-3; a shading isolation rubber frame-4; a sealing ring-5; an inner brick body-11; an outer brick body-12; butt joint surface-13; a receiving groove-14; a socket-15; a first limit convex edge-111; a second limit convex edge-121; a light guide bubble group-21; reference light guide bubble-211; a first mating light directing bubble-212; a second mating light directing bubble-213; a light source plate-31; a light source-32; a recess-311.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be clearly and completely described below with reference to the specific embodiments of the present invention and the accompanying drawings. It is to be understood that the described embodiments are merely exemplary of the invention, and not restrictive of the full scope of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1 and 2, the light guide illumination hollow glass brick for indoor design of the present invention comprises a glass brick body 1, a light guide plate 2 disposed in the glass brick body 1, and a light emitting member 3 illuminating the light guide plate 2 and detachably disposed at the bottom of the glass brick body 1. In the light guide illumination hollow glass brick, the light guide plate 2 is arranged, so that the light effect requirement of the glass brick can be met, the dismounting and replacement requirements of the light emitting piece 3 can be met, and the practicability of the light guide illumination hollow glass brick is improved; but also can reduce the cost and simplify the manufacturing process.

In order to achieve the above object, the parts of the light guide illumination hollow glass block can be arranged in various ways, and the structure of each part is described in detail below by taking a specific embodiment as an example.

The glass brick body 1 can be made of glass silicon, is internally of a hollow structure, and can be formed by high-temperature fusion and butt joint of an inner brick body 11 and an outer brick body 12 which are of symmetrical structures, wherein the inner brick body 11 is fixed on a wall body and is close to the wall body, and the outer brick body 12 is far away from the wall body. The bottom of the inner side brick body 11 (when the glass brick is attached to a wall surface, the side close to the ground) and the bottom of the outer side brick body 12 are both provided with grooves, after the inner side brick body 11 and the outer side brick body 12 are butted and fused, a containing groove 14 extending along the butting face 13 of the inner side brick body 11 and the outer side brick body 12 is formed by the grooves of the two parts, namely, the containing groove 14 extending along the butting face 13 of the inner side brick body 11 and the outer side brick body 12 is arranged at the bottom of the glass brick body 1, and the containing groove 14 is symmetrical about the butting face 13. The degree of depth of storage tank 14 can specifically be set for according to the demand, and glass brick body 1 is all run through at storage tank 14's both ends, and storage tank 14's tank bottom is equipped with socket 15, by the inside of socket 15 intercommunication storage tank 14 and glass brick body 1. And the length of the insertion opening 15 (dimension in the extending direction of the receiving groove 14) is slightly larger than the length of the light guide plate 2 (dimension in the extending direction of the receiving groove 14), and the width of the insertion opening 15 (dimension perpendicular to the length of the insertion opening 15) is slightly larger than the thickness of the light guide plate 2.

As shown in fig. 2 and 3, the inner wall of the inner brick body 11 is further provided with a first limiting convex edge 111 extending along the circumferential direction of the abutting surface 13, and the inner wall of the outer brick body 12 is provided with a second limiting convex edge 121 extending along the circumferential direction of the abutting surface 13. The first limiting convex edge 111 and the second limiting convex edge 121 are respectively positioned at two sides of the socket 15 and at least partially overlapped with the socket 15 along the direction from the inner side brick body 11 to the outer side brick body 12, so that the width between the first limiting convex edge 111 and the second limiting convex edge 121 is approximately the same as the thickness of the light guide plate 2, and the light guide plate 2 is limited and fixed by the first limiting convex edge 111 and the second limiting convex edge 121.

The first and second limiting convex edges 111 and 121 can be constructed in various ways. In one example, the first position-limiting ledge 111 continuously surrounds the top wall and the two side walls of the inner brick body 11, and the second position-limiting ledge 121 continuously surrounds the top wall and the two side walls of the outer brick body 12. The structure is simple, and the processing and the manufacturing are convenient; improve follow-up light guide plate 2's fixed fastness, reduce the spacing protruding edge 121 of second simultaneously and set a camera to sheltering from, guarantee the light efficiency continuity between the adjacent glass brick as far as possible.

After the glass brick body 1 is processed, the light guide plate 2 is inserted from the insertion opening 15. Can be at the work progress of interior decoration, specifically before pasting and establishing the glass brick, insert light guide plate 2 into glass brick body 1, like this the user can be as required, select the light guide plate 2 of corresponding light efficiency. Of course, also can insert light guide plate 2 before leaving the factory, guarantee light guide plate 2's fixed fastness to obtain better product reliability, prevent into the ash or intake in the glass brick body 1.

The light guide plate 2 may be fixed in an adhesive manner whenever the light guide plate 2 is installed in the glass block body 1. The periphery of the two sides of the light guide plate 2 is provided with adhesive, and the light guide plate 2 is bonded with the first limit convex edge 111 and the second limit convex edge 121, so as to be fixed in the glass brick body 1. The height of the light guide plate 2 is slightly larger than the height inside the glass brick body 1, and after the light guide plate 2 is fixed, the bottom of the light guide plate 2 extends into the accommodating groove 14 through the inserting opening 15, so that the light emitting part 3 can illuminate the light guide plate 2. And the bottom cover of light guide plate 2 is equipped with sealing washer 5, is sealed the clearance between light guide plate 2 and socket 15 by sealing washer 5 to prevent that dust and steam from getting into inside the glass brick body 1.

A layer of light guide plate 2 may be disposed between the first limiting convex edge 111 and the second limiting convex edge 121, or at least two layers of light guide plates 2 may be disposed. When the light guide plate 2 is arranged, the light guide plate 2 can be made of plastic and is a semitransparent or frosted light homogenizing plate, light rays are injected into the light guide plate 2 and then scattered and emitted out of the surface of the light guide plate 2, and therefore the light guide plate 2 presents an even lighting effect.

As shown in fig. 4, when at least two light guide plates 2 are disposed, two adjacent light guide plates 2 are spaced and fixed by a light shielding and isolating rubber frame 4, and a sealing ring 5 is sleeved outside the multiple light guide plates 2. The bottom of the shading isolation rubber frame 4 slightly exceeds the light guide plate 2, so that the bottom of the shading isolation rubber frame 4 is abutted against the luminous piece 3, other parts are abutted against the glass brick body 1, the shading effect is improved by the shading isolation rubber frame 4, and the phenomenon of undesirable light leakage caused by gaps between the luminous piece 3 and the light guide plate 2 is avoided.

Further, the material of each light guide plate 2 may be glass, but may be other materials. The reference light guide plate positioned at the inner side (close to the inner side brick body 11) is distributed with a plurality of reference light guide bubbles 211, the reference light guide bubbles 211 can be randomly arranged, after the light is incident to the reference light guide plate, the whole brightness of the reference light guide plate is not changed greatly, and bright spots only appear at the positions of the reference light guide bubbles 211. The other matched light guide plates are provided with matched light guide bubbles corresponding to the reference light guide bubbles 211, and after light enters the corresponding matched light guide plates, the brightness change of the whole matched light guide plates is not large, and bright spots only appear at the positions of the matched light guide bubbles on the matched light guide plates. From inside to outside, each reference light guide bubble 211 is staggered with the corresponding matched light guide bubble in sequence to form a plurality of light guide bubble groups 21, namely, in the same light guide bubble group 21, the reference light guide bubble 211 is staggered with the adjacent matched light guide bubble, the adjacent matched light guide bubble with the reference light guide bubble 211 is staggered with the adjacent matched light guide bubble at the outer side, and the matched light guide bubbles are staggered and arranged in sequence to form a group of light guide bubble groups 21.

When the light is emitted, the light guide bubbles of each layer of the light guide plate 2 can gradually emit light from inside to outside, namely, all the reference light guide bubbles 211 of the reference light guide plate emit light first, and the light guide bubbles matched with the light guide plate do not emit light; then, all the matching light guide bubbles of the matching light guide plate adjacent to the outside emit light, and the remaining matching light guide bubbles of the matching light guide plate and the reference light guide bubbles 211 of the reference light guide plate do not emit light; then, all the matching light guide bubbles of the third layer of the matching light guide plate close to the outer side emit light, and the matching light guide bubbles of the other matching light guide plates and the reference light guide bubbles 211 of the reference light guide plate do not emit light, and the above circulation is repeated to emit light in sequence. Therefore, gorgeous lighting effects from far to near and in a staggered manner are formed, and even a starry sky or meteor and other gorgeous lighting effects can be formed through further arrangement.

The following description will specifically describe the arrangement of the light guide bubble group by taking the formation of the starry sky light effect as an example. As shown in fig. 5, the light guide plate 2 is provided with two layers, each light guide bubble group 21 includes a reference light guide bubble 211 and a first matching light guide bubble 212 located outside, and the reference light guide bubble 211 and the first matching light guide bubble 212 alternately emit light in sequence. Further, for realizing more lifelike star sky light effect, the diameters of the reference light guide bubbles 211 and the first cooperation light guide bubbles 212 are both smaller than 0.5mm, and are parallel to the direction of the reference light guide plate, and the distance between the reference light guide bubbles 211 and the corresponding first cooperation light guide bubbles 212 is smaller than 0.1 mm.

Of course, the diameter, distance, etc. of each light guide bubble can also be set to other sizes, and in this case, the starry sky light effect can be realized by arranging at least three layers of light guide plates 2.

The following description will specifically describe the arrangement of the light guide bubble group by taking the formation of the meteoric effect as an example. As shown in fig. 6, at this time, the light guide plate 2 is provided with three layers, each light guide bubble group 21 includes a reference light guide bubble 211, a first mating light guide bubble 212 located in the middle, and a second mating light guide bubble 213 located in the outer side, and the reference light guide bubble 211, the first mating light guide bubble 212, and the second mating light guide bubble 213 alternately emit light in sequence. The reference light guide bubbles 211, the first matching light guide bubbles 212 and the second matching light guide bubbles 213 can be obliquely arranged or vertically arranged, and the meteor lighting effect formed in the vertical arrangement can also be called as raindrop lighting effect.

Further, in order to realize more realistic meteor lighting effect, the diameters of the reference light guide bubble 211, the first matching light guide bubble 212 and the second matching light guide bubble 213 are all 0.5-1mm and are parallel to the reference light guide plate direction, the distance between the reference light guide bubble 211 and the first matching light guide bubble 212 is 0.3-0.5mm, and the distance between the first matching light guide bubble 212 and the second matching light guide bubble 213 is 0.5-0.8 mm.

Of course, the diameter, distance, etc. of each light guide bubble may be set to other dimensions, and in this case, the meteoric effect may be achieved by providing at least four light guide plates 2.

As shown in fig. 7 and 8, the light emitting member 3 includes a light source plate 31 and a light source 32 fixed to the light source plate 31. The material of light source board 31 can be the rubber material, specifically is the opaque rubber material of stereoplasm, certain elasticity to can insert and fix in storage tank 14 from the one end of storage tank 14, light source board 31 specifically can directly be placed on the rubber face with glass brick body 1 viscose at the wall body. The light source 32 may be a LED strip fixed on the light source board 31 and facing the light guide plate 2.

Further, a groove 311 is formed at the top of the light source plate 31, and the light source 32 is disposed at the bottom of the groove 311 to reduce light leakage. And along the extending direction of the receiving groove 14, the light source plate 31 is sequentially provided with a plurality of grooves 311 at intervals, each groove 311 is provided with a light source 32, the light sources 32 in different grooves 311 illuminate the light guide plates 2 in different glass brick bodies 1, that is, the light guide plates 2 in a plurality of glass brick bodies 1 arranged along the horizontal direction share one light source plate 31. So set up, conveniently place illuminating part 3 in storage tank 14, for the tearing open of light source 32 trade, the maintenance provides conveniently, and for the later stage through the luminous colour of changing light source 32 etc. in order to realize different illuminating effect, it is convenient to provide.

It should be noted that, along the direction from the first limiting convex edge 111 to the second limiting convex edge 121, the number of rows of the grooves 311 is the same as the number of layers of the light guide plate 2. As shown in fig. 7, when one layer of the light guide plate 2 is provided, a row of grooves 311 is provided; when two layers of light guide plates 2 are arranged, two rows of grooves 311 are arranged; as shown in fig. 8, when three light guide plates 2 are provided, three rows of grooves 311 are provided, and the light sources 32 in the different rows of grooves 311 illuminate the light guide plates 2 of the corresponding layers, respectively.

In addition, the light source board 31 is provided with a first light guide board (not shown in the figure) on the outer side surface facing the outer brick body 12, the top of the light source board 31 is provided with a second light guide board connected with the first light guide board and extending into the groove 311, the first light guide board is a layer and provided with light guide auxiliary bubbles, the second light guide board presents uniform illumination effect, and the second light guide board inclines towards the bottom of the light source board 31 along the outer side surface of the light source board 31 to the direction of the groove 311. The structure is simple, and the possibility of arranging the second light guide plate is provided; the light guide plates 2 in the upper and lower adjacent glass brick bodies 1 can be connected by a second auxiliary light guide plate, so that the condition that the light effect is influenced by black lines at the position of the light source plate 31 is reduced; the bottom of the light guide plate 2 is slightly illuminated by the first auxiliary light guide plate to slightly weaken the starry sky or meteor light effect at the bottom of the light guide plate 2, so that the light spot formed by the first auxiliary light guide plate is connected with the light spot formed by the second auxiliary light guide plate, and then the visual staying effect of human eyes is combined to approach the perfect starry sky or meteor light effect as far as possible.

The light source 32 is electrically connected to the control unit through a signal line. When a layer of light guide plates 2 is provided, the light sources 32 can be controlled synchronously by the control unit, i.e. the light guide plates 2 in all the glass tile bodies 1 emit light synchronously. But also the lighting effect of the light sources 32 may be identical, e.g. same brightness, same extension and same color temperature, etc. At this time, the grooves 311 in the same row on the light source plate 31 can be communicated with each other, so that each groove 311 can share one light source 32, which is labor-saving. Of course, the lighting effect of the light sources 32 may not be completely the same, for example, the light sources 32 in the same column of glass block bodies 1 arranged vertically are the same, and at least some of the light sources 32 in each row of glass block bodies 1 arranged horizontally are different, specifically, different brightness, different color, or different color temperature, etc.; alternatively, each light source 32 may be controlled by the control unit individually, so as to achieve different dynamic variation effects according to the requirements.

When at least two layers of light guide plates 2 are provided, the lighting effect of the light sources 32 in all the grooves 311 can be set according to the requirement. In all the glass brick bodies 1, the light guide plates 2 on the same layer are simultaneously illuminated, and the light guide plates 2 on different layers are sequentially and alternately illuminated to form a starry sky or meteor effect and the like.

The control unit may include a control circuit board, specifically, a single chip microcomputer (or CPU) and an embedded system (or an android system). The control unit is connected with the power supply unit. The control unit preferably comprises a wireless module to receive a wireless signal command, such as WiFi, so that a user can use WiFi to connect to the glass wall to control the display effect of the glass wall.

As shown in fig. 9 and 10, the glass wall of the present invention includes light guide illuminating hollow glass blocks arranged in a matrix, and the light guide illuminating hollow glass blocks are the light guide illuminating hollow glass blocks described above. In this glass wall, through setting up light guide plate 2, can realize the light efficiency demand of glass brick promptly, can realize the dismouting change demand of illuminating part 3 again, promote the practicality of light guide illumination hollow glass brick.

While the present invention has been described with reference to the embodiments shown in the drawings, the present invention is not limited to the embodiments, which are illustrative and not restrictive, and it will be apparent to those skilled in the art that various changes and modifications can be made therein without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (10)

1. A light-guide illuminated hollow glass tile for interior design, comprising:

the glass brick comprises a glass brick body, wherein the glass brick body is composed of an inner side brick body and an outer side brick body which are mutually butted, a containing groove extending along the butted surface of the inner side brick body and the outer side brick body is arranged at the bottom of the glass brick body, two ends of the containing groove penetrate through the glass brick body, a socket communicated with the inside of the glass brick body is arranged at the bottom of the containing groove, a first limiting convex edge which is positioned on one side of the socket and extends along the circumferential direction of the butted surface is arranged on the inner wall of the inner side brick body, and a second limiting convex edge which is positioned on the other side of the socket and extends along the circumferential direction of the butted surface is arranged on the inner wall;

the light guide plate is fixed inside the glass brick body, is limited by the first limiting convex edge and the second limiting convex edge, and extends into the accommodating groove through the socket;

the light emitting piece comprises a light source plate and a light source, wherein one end of the accommodating groove is inserted into the accommodating groove, and the light source is fixed on the light source plate to illuminate the light guide plate.

2. The light guide illumination hollow glass brick for indoor design according to claim 1, wherein at least two layers of the light guide plates are arranged between the first limiting convex edge and the second limiting convex edge, the adjacent two layers of the light guide plates are fixed at intervals by a light shielding isolation rubber frame, a plurality of reference light guide bubbles illuminated by the light source are distributed on the reference light guide plate positioned at the inner side, the rest of the matched light guide plates are provided with matched light guide bubbles which correspond to the reference light guide bubbles and are sequentially staggered from inside to outside, and the light shielding isolation rubber frame is abutted to the light source plate and the glass brick body;

the light emitting member includes light sources respectively corresponding to the reference light guide plate and the mating light guide plate, and the light sources alternately emit light in sequence.

3. The light guide lighting hollow glass block for indoor design according to claim 2, wherein the light guide plate is provided with two layers, each of the reference light guide bubbles and the corresponding mating light guide bubbles constitute a starry sky light effect; or

The light guide plate is provided with three layers, and each reference light guide bubble and the corresponding matched light guide bubble form a meteor light effect.

4. The light guide lighting hollow glass tile for indoor design according to claim 3, wherein when the reference light guide bubbles and the matching light guide bubbles constitute a starry sky light effect, the reference light guide bubbles and the matching light guide bubbles are both less than 0.5mm in diameter and parallel to the reference light guide plate direction, and the distance between the reference light guide bubbles and the corresponding matching light guide bubbles is less than 0.1 mm;

when the reference light guide bubbles and the rest of the matching light guide bubbles form a meteor light effect, the diameters of the reference light guide bubbles and the matching light guide bubbles are between 0.5mm and 1mm and are parallel to the direction of the reference light guide plate, the distance between the reference light guide bubbles and the matching light guide bubbles corresponding to the middle is 0.3 mm to 0.5mm, and the distance between the matching light guide bubbles corresponding to the middle and the outer sides is 0.5mm to 0.8 mm.

5. A light-guiding illuminating hollow glass block for interior design according to claim 1, characterized in that the light-guiding plate is provided with a layer, and the light-guiding plate is a translucent or frosted light homogenizing plate.

6. A light guide lighting hollow glass tile for indoor design according to any of claims 2-5, characterized in that the top of the light source board is provided with a groove, the light source is arranged at the bottom of the groove and facing the light guide board.

7. A light guide lighting hollow glass block for indoor design according to claim 6, characterized in that along the direction of the butt joint face of the inner brick body and the outer brick body, the light source plate is sequentially provided with a plurality of grooves at intervals, each groove is provided with the light source, wherein the light sources in different grooves illuminate the light guide plates in different glass block bodies.

8. The light guide illumination hollow glass tile for indoor design as claimed in claim 6, wherein the outer side of the light source board facing the outer tile body is provided with a first light guide board, the top of the light source board is provided with a second light guide board connected with the first light guide board and extending into the groove, the first light guide board is a layer and provided with light guide bubbles, the second light guide board presents uniform illumination effect and inclines towards the bottom of the light source board along the outer side of the light source board to the groove.

9. A light guiding illuminated hollow glass tile for indoor design according to any of claims 1-5, characterized in that the first limiting ledge is located at the top wall and the side wall of the inner tile body;

the second limiting convex edge is positioned on the top wall and the side wall of the outer side brick body.

10. A glass wall comprising a matrix arrangement of light-guide illuminated hollow glass blocks, said light-guide illuminated hollow glass blocks being as defined in any one of claims 1 to 9.

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