CN112169354A - Conductive building block capable of selecting light transmission direction - Google Patents

Abstract

The invention provides a conductive building block capable of selecting a light transmission direction, which comprises a top cover, a circuit board and a light emitting assembly, wherein the top cover is provided with a light guide plate; the top cover is a hollow block made of light-tight material, a light guide wedge column is formed on the outer side of the top cover, and a light hole communicated with the inner space of the top cover is concavely formed on the outer end surface of the light guide wedge column; the circuit board is arranged in the top cover and comprises an electrode loop; the light-emitting component is arranged on the circuit board and is electrically connected with the electrode loop; therefore, light can only be emitted out through the light holes of the light guide wedge columns, so that the light-emitting patterns of objects such as car lamps, eyes or illuminating lamps of buildings can be simulated correctly, and the appearance shape of the car lamps can be simulated by utilizing the shape of the wedge columns protruding out of the top cover, so that the reality degree of the building block model is increased; the light guide wedge columns can be arranged on the top surface or the side surface of the top cover so as to increase the variation degree of the building block combination.

Description

Conductive building block capable of selecting light transmission direction

Technical Field

The invention relates to a conductive building block with a light-emitting component and an electric connection loop arranged inside, in particular to a conductive building block with a light hole on a top cover and capable of selecting a light transmission direction.

Background

In the prior art, the top cover of the conductive building block is made of a light-transmitting material, the light-emitting component and a related electric connection loop are arranged in the top cover, after the light-emitting component is powered through the electric connection loop, the light-emitting component can radiate light rays radially and simultaneously towards all angles, and the light rays penetrate through the top cover and irradiate the outside of the top cover, so that the conductive building block is in an integrally luminous state;

however, when a user constructs a model of an automobile, a building, an animal or an anthropomorphic doll, the light is limited to be emitted from only a specific region of the building block to simulate the light-emitting state of objects such as lamps of the automobile, illuminating lamps of the building, and the like, eyes, and the like.

Therefore, the conductive building blocks capable of emitting light in the prior art need to be improved.

Disclosure of Invention

In view of the foregoing drawbacks and deficiencies of the prior art, the present invention provides a conductive building block capable of selecting a light transmission direction, wherein a top cover of the conductive building block is made of a non-light-transmissive material, and the top cover is provided with a light-transmissive wedge pillar having a light-transmissive hole for selecting the light transmission direction.

In order to achieve the above object, the present invention provides a conductive building block capable of selecting a light transmission direction, comprising:

the top cover is a hollow block body made of light-tight materials, an opening is formed in one side of the top cover, at least one wedge hole is formed in the opening in the inner space of the top cover, a light guide wedge column is formed in the outer side of the top cover in a protruding mode, a light transmission hole is formed in the outer end face of the light guide wedge column in a concave mode, and the light transmission hole is communicated with the inner space of the top cover; the shape of the light guide wedge column corresponds to the shape of at least one wedge hole;

the circuit board is arranged in the top cover and comprises an electrode loop, and the electrode loop faces to the opening; and

and the light-emitting component is arranged on the circuit board and positioned in the inner space of the top cover, and the light-emitting component is electrically connected with the electrode loop.

The invention has the advantages that:

first, the top cap of electrically conductive building blocks adopts the preparation of opaque material, and when light-emitting component radiated light, light only can penetrate the light trap of leaded light wedge post and jets out, borrows this control light can radiate the angle of wearing out the top cap to can correctly simulate the car light of car, the light etc. of building, the luminous patterns of objects such as eyes, also can utilize the wedge post to stick out the shape of top cap and make the emulation to the car light shape simultaneously, increase the degree of reality of building blocks model.

Second, the light guide wedge column can be arranged on the top surface or one side surface of the top cover as required to increase the variation degree of the building block combination, and the light guide wedge column can be applied to occasions except for simulating automobile lamps, such as illuminating lamps of buildings.

Thirdly, the light guide wedge column can also be embedded with other conductive building blocks, and the functions of the building block are further increased.

Furthermore, the position of the light emitting assembly corresponds to the position of the light hole of the light guide wedge column, and viewed from the normal direction of the circuit board, an extension line of the axis of the light hole passes through the upper part of the light emitting assembly.

Furthermore, at least one connecting wedge column is further formed on the outer side of the top cover in a protruding mode, and the shape of the at least one connecting wedge column corresponds to the shape of the at least one wedge hole.

Furthermore, a plurality of embedded ribs are protruded from the inner wall surface of the top cover, the embedded ribs extend to the opening, and the embedded ribs surround to form at least one wedge hole.

Furthermore, the circuit board has a plurality of circuit board engagement grooves recessed in the periphery thereof, and the plurality of circuit board engagement grooves are respectively engaged with the plurality of engagement ribs.

Furthermore, a circuit board abutting part is formed on the inner wall surface of the top cover, and the top surface of the circuit board abuts against the circuit board abutting part.

Further, the circuit board abutting portion is a stepped surface surrounding a coil.

Furthermore, the circuit board seals the opening, and the circuit board is made of opaque material; the light-emitting component is positioned on one side of the circuit board far away from the opening.

Drawings

Fig. 1 is a perspective view of the present invention.

Fig. 2 is another perspective view of the present invention.

Fig. 3 is an exploded view of the assembly of the present invention.

FIG. 4 is a schematic longitudinal sectional view of the center of the light hole according to the present invention.

FIG. 5 is a cross-sectional view of the center of the light hole according to the present invention.

Description of the symbols

10 top cover 11 opening

12 inner space 13 wedge hole

Outer end face of 14 light guide wedge 141

142 light hole 15 connecting wedge column

16 fitting rib 17 circuit board abutting part

20 circuit board 21 electrode loop

22 circuit board fitting groove 30 light-emitting component

N1 Normal N2 Axis

Detailed Description

The technical means adopted by the invention to achieve the predetermined object of the invention are further described below with reference to the drawings and the preferred embodiments of the invention.

Referring to fig. 1 to 3, the light-transmitting direction-selectable conductive building block of the present invention includes a top cover 10, a circuit board 20, and a light-emitting element 30.

The top cover 10 is a hollow block made of opaque material, and an opening 11 is formed on one side of the top cover 10; the inner space 12 of the top cover 10 forms two wedge holes 13 at the opening 11, but the number of the wedge holes 13 is not limited to this, and the number of the wedge holes 13 may be only one;

referring to fig. 1, 3 and 5, a light guide wedge 14 is protruded from an outer side of the top cover 10, a light hole 142 is concavely formed on an outer end surface 141 of the light guide wedge 14, and the light hole 142 is communicated with the inner space 12 of the top cover 10; the shape of the light guide wedge column 14 corresponds to the shape of the wedge hole 13, namely when the two conductive building blocks are combined with each other, the light guide wedge column 14 of one conductive building block can be clamped and fixed with the wedge hole 13 of the other conductive building block; in the present embodiment, the top cover 10 has two protruding wedges on the top surface and the front side surface, wherein the two wedges on the top surface are two connecting wedges 15, and the two wedges on the front side surface are the light guide wedge 14 and one connecting wedge 15, respectively; the shape of the connecting wedge 15 corresponds to the shape of the wedge hole 13, that is, when two conductive building blocks of the present invention are combined with each other, the connecting wedge 15 of one conductive building block can be engaged with and fixed to the wedge hole 13 of the other conductive building block, but the number and the positions of the connecting wedge 15 are not limited to this, and only the connecting wedge 15 is located at the outer side of the top cover 10, for example, only one connecting wedge 15 may be provided at the side of the top cover 10, even the wedge of the present invention may be all the light guiding wedge 14 without the connecting wedge 15, and so on; in addition, the light guide wedge 14 may also be located on the top surface of the top cover 10;

in the embodiment, the inner wall surface of the top cover 10 is protruded with a plurality of embedding ribs 16, the embedding ribs 16 extend to the opening 11, and the embedding ribs 16 surround to form two wedge holes 13, the wedge holes 13 are designed to be surrounded by a plurality of surrounding and spaced embedding ribs 16, so that the material used for forming the wedge holes 13 can be reduced, and meanwhile, when the manufacturing method of the top cover 10 is plastic injection molding, the embedding ribs 16 can be easily manufactured integrally with the top cover 10.

In the embodiment, a circuit board abutting portion 17 is formed on the inner wall surface of the top cover 10, and the circuit board abutting portion 17 is a stepped surface surrounding a circle, but not limited thereto, only the circuit board abutting portion 17 can limit the circuit board from moving in a direction away from the opening 11, for example, the circuit board abutting portion 17 may also be a plurality of bumps protruding from the inner wall surface of the top cover 10 and disposed at intervals around the inner wall surface.

Referring to fig. 2 to 4, the circuit board 20 is disposed in the top cover 10, the circuit board 20 includes an electrode loop 21, the electrode loop 21 faces the opening 11, the light emitting element 30 is mounted on the circuit board 20, and the light emitting element 30 is electrically connected to the electrode loop 21; therefore, after the wedge column of the power supply building block with the power supply contact protruding from the top end of the other wedge column penetrates upwards and is clamped with the wedge hole 13 of the conductive building block, the power supply contact of the power supply building block can be electrically connected with the electrode loop 21 of the conductive building block, and the light-emitting component 30 can emit light;

in the present embodiment, a plurality of circuit board fitting grooves 22 are concavely formed on the periphery of the circuit board 20, and the circuit board fitting grooves 22 are respectively fitted with the fitting ribs 16 on the inner wall surface of the top cover 10 to limit the downward movement of the circuit board 20 and the separation from the top cover, but not limited thereto, the circuit board 20 of the present invention may be configured without the circuit board fitting grooves 22, and limit bumps are formed on the inner wall surface of the top cover 10 to limit the downward movement of the circuit board 20; in the embodiment, the circuit board 20 seals the opening 11 of the top cover, the light emitting component 30 is located on a side of the circuit board 20 away from the opening 11, and the circuit board 20 is made of a light-tight material, so that light emitted or reflected toward the opening 11 can be reflected by the circuit board 20 and then pass through the top cover 10 through the light-transmitting hole 142, thereby preventing the light from directly passing through the opening 11 to be lost, and improving the luminance of the light emitted by the present invention.

Referring to fig. 4 and 5, in the present embodiment, the position of the light emitting element 30 corresponds to the position of the light hole 142 of the light guiding wedge 14, specifically, the normal N1 of the circuit board 20 is perpendicular to the axis N2 of the light hole 142, and the extension line of the axis N2 of the light hole 142 passes through the upper side of the light emitting element 30 when viewed from the normal N1 of the circuit board 20, but not limited thereto, in other preferred embodiments, the position of the light emitting element 30 corresponding to the position of the light hole 142 may be that the light emitting element 30 is directly disposed on the axis N2 of the light hole 142, for example, the circuit board 20 may further include a sub-circuit board perpendicular to the opening 11, and the light emitting element 30 is mounted on the sub-circuit board at a position passing through N2, which may further increase the light emitting brightness although the cost is higher; in addition, when the inner wall surface of the top cover 10 has a good light reflection effect, the position of the light emitting element 30 does not need to correspond to the position of the light guiding wedge 14.

Referring to fig. 1 and fig. 2, when the power supply building block of the present invention is used, it is necessary to match the power supply building block not according to the present invention, and the power supply building block is a conventional art and is not described in detail; the power supply building block is provided with a power supply loop, the top end of a wedge column of the power supply building block protrudes with a power supply contact, when the wedge column of the power supply building block upwards penetrates and is clamped with the wedge hole 13 of the invention, the power supply contact of the power supply building block contacts the electrode loop 21 of the invention, so that the electrode loop 21 is electrically connected with the power supply loop, and the light-emitting component 30 emits light; in a preferred embodiment of the building block assembly, the present invention is installed at a position of a lamp of an automobile building block assembly with power supply capability, and the opening of the light hole 142 faces the front of the automobile building block assembly to simulate the lighting effect of the lamp, but not limited thereto, the present invention can also be used for simulating the lighting pattern of objects such as lighting lamps of buildings, eyes, etc., and therefore, the present invention can also be applied to other types of building block assemblies such as buildings, animal models, or anthropomorphic doll models, etc.

In summary, the light emitting assembly is arranged in the top cover, the top cover is made of opaque material, and light emitted by the light emitting assembly can only penetrate through the light holes and out of the top cover.

Although the present invention has been described with reference to a preferred embodiment, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (8)

1. The utility model provides a but selection light transmission direction's electrically conductive building blocks which characterized in that contains:

the light guide wedge column is formed in the outer side of the top cover in a protruding mode, a light transmission hole is formed in the outer end face of the light guide wedge column in a concave mode, and the light transmission hole is communicated with the inner space of the top cover; the shape of the light guide wedge column corresponds to the shape of the at least one wedge hole;

the circuit board is arranged in the top cover and comprises an electrode loop, and the electrode loop faces the opening; and

and the light-emitting component is arranged on the circuit board and is positioned in the inner space of the top cover, and the light-emitting component is electrically connected with the electrode loop.

2. The light transmission direction selectable conductive building block of claim 1, wherein: the position of the light emitting component corresponds to the position of the light transmission hole of the light guide wedge column, the light transmission hole is viewed from the normal direction of the circuit board, and the extension line of the axis of the light transmission hole passes through the upper part of the light emitting component.

3. The light transmission direction selectable conductive building block of claim 1, wherein: at least one connecting wedge column is further formed on the outer side of the top cover in a protruding mode, and the shape of the at least one connecting wedge column corresponds to the shape of the at least one wedge hole.

4. The light transmission direction selectable conductive building block of claim 1, wherein: the inner wall surface of the top cover is provided with a plurality of embedded ribs in a protruding mode, the embedded ribs extend to the opening, and the embedded ribs surround to form the at least one wedge hole.

5. The light transmission direction selectable conductive building block of claim 4, wherein: the periphery of the circuit board is concavely provided with a plurality of circuit board embedding grooves, and the plurality of circuit board embedding grooves are respectively embedded with the plurality of embedding ribs.

6. The light transmission direction selectable conductive building block of claim 1, wherein: a circuit board abutting part is formed on the inner wall surface of the top cover, and the top surface of the circuit board abuts against the circuit board abutting part.

7. The light transmission direction selectable conductive building block of claim 6, wherein: the circuit board abutting part is a step surface which is encircled to be in a ring shape.

8. The light transmission direction selectable conductive building block of claim 1, wherein:

the circuit board seals the opening and is made of opaque materials;

the light emitting component is positioned on one side of the circuit board far away from the opening.

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