CN101676622A - Luminous structure with ring-shaped luminous effect - Google Patents

Abstract

The invention relates to a luminous structure with ring-shaped luminous effect, comprising a light guide module, a capping module and a luminous module. The light guide module comprises a hollow lightguide body and a reflection coating formed on the inner surface of the hollow light guide body; the capping module comprises a first capping body arranged on one side end of the hollow light guide body and a second capping body arranged on the contrary side end of the hollow light guide body; the luminous module is provided with a plurality of first luminous components arranged between the hollowlight guide body and the first capping body; and a first ray generated by the first luminous component is sent to the hollow light guide body, and the first ray is guided by the hollow light guide body and reflected by the reflection coating, thus the hollow light guide body generates ring-shaped luminous effect.

Description

Ray structure with annular illumination effect

Technical field

The present invention relates to a kind of ray structure, relate in particular to a kind of ray structure with annular illumination effect.

Background technology

The invention of electric light can be described as the life style that has changed the whole mankind up hill and dale, if our life does not have electric light, night or weather conditions not good the time after, the work of all will be stopped; If be subject to illumination, the utmost point has can make building construction mode or human life style all thoroughly change, and therefore the whole mankind will can't improve, the age that stays on and fall behind.

So, today employed on the market lighting apparatus, for example: fluorescent lamp, tengsten lamp even the more popular till now Electricity-saving lamp bulb of being accepted are widely used in the middle of the daily life all.Yet this type of electric light has fast, the high power consumption of optical attenuation mostly, be easy to generate high heat, the life-span is short, frangible or shortcoming such as difficult recovery.Moreover; the color rendering of traditional fluorescent lamp is relatively poor; so produce pale light and be out of favour; in addition because principle of luminosity is 120 times quick flowing in a second of fluorescent tube two utmost point electronics; when firm unlatching and electric current instability, cause flicker easily; this phenomenon is considered to cause the arch-criminal of domestic high rate of myopia usually; but this problem can be solved by the fluorescent tube of repacking with " high-frequency electrical minor stabilizer "; its high-frequency electrical minor stabilizer not only can fall 20% to the power consumption of traditional fluorescent lamp again; when lighting a lamp because of high frequency moment again; the light wave of output is highly stable; therefore almost flicker free takes place; and when power supply voltage variation or fluorescent tube are in low temperature, be not easy to produce flicker, this helps the protection of eyesight.Yet the stabilizer of general Electricity-saving lamp bulb and power-saving lighting tube all is fixed, if eliminate the words of trade-in, must connect stabilizer abandons together, moreover no matter fluorescent tube how power saving again,, still inevitably environment is caused serious pollution after discarded because of it contains the coating of mercury.

So as from the foregoing, above-mentioned existing light-emitting device on reality is used, obviously has inconvenience and exists with disappearance.

Summary of the invention

The technological means of the present invention in order to deal with problems is to provide a kind of ray structure with annular illumination effect, and it is by the cooperation of a hollow light guide body, at least one light emitting module and two capping bodies, to produce the illumination effect of annular.

According to above-mentioned, wherein a kind of scheme of the present invention provides a kind of ray structure with annular illumination effect, and it comprises: a light guide module, a capping module, an and light emitting module.Wherein, this light guide module has the reflectance coating that a hollow light guide body and forms in the inner surface of this hollow light guide body.This capping module has the second capping body that first a capping body and that is arranged at a side of this hollow light guide body is arranged at another opposite side of this hollow light guide body.This light emitting module has a plurality of first luminescence components that are arranged between this hollow light guide body and this first capping body.

For this reason, first light that these first luminescence components are produced is invested this hollow light guide body, and this first light is by the guiding of this hollow light guide body and the reflection of this reflectance coating, so that this hollow light guide body produces the illumination effect of annular.

Therefore, the invention has the advantages that: by the cooperation of a hollow light guide body, at least one light emitting module and two capping bodies, to produce the illumination effect of annular.

Describe the present invention below in conjunction with the drawings and specific embodiments, but not as a limitation of the invention.

Description of drawings

Figure 1A has the three-dimensional exploded view of first embodiment of the ray structure of annular illumination effect for the present invention;

Figure 1B has the three-dimensional combination figure of first embodiment of the ray structure of annular illumination effect for the present invention;

Fig. 1 C is the 1C-1C profile of Figure 1B of the present invention;

The ray structure that Fig. 2 A has an annular illumination effect for the present invention is the schematic perspective view of the second capping body in a second embodiment;

Fig. 2 B has the side cutaway view of second embodiment of the ray structure of annular illumination effect for the present invention;

Fig. 3 A has the three-dimensional exploded view of the 3rd embodiment of the ray structure of annular illumination effect for the present invention;

Fig. 3 B has the generalized section of the 3rd embodiment of the ray structure of annular illumination effect for the present invention;

Fig. 4 has the generalized section of the 4th embodiment of the ray structure of annular illumination effect for the present invention;

Fig. 5 has the three-dimensional exploded view of the 5th embodiment of the ray structure of annular illumination effect for the present invention;

Fig. 6 A has the three-dimensional exploded view of the 6th embodiment of the ray structure of annular illumination effect for the present invention;

Fig. 6 B has the generalized section of the 6th embodiment of the ray structure of annular illumination effect for the present invention;

Fig. 7 has the generalized section of the 7th embodiment of the ray structure of annular illumination effect for the present invention;

Fig. 8 is the perspective exploded view of the 8th embodiment of light guide module of the present invention; And

Fig. 9 is the perspective exploded view of the 9th embodiment of light guide module of the present invention.

Wherein, Reference numeral

(first embodiment)

Light guide module 1a hollow light guide body 10a

Reflectance coating 11a

The capping module 2a first capping body 21a

The first flat part 210a

The first opening 211a

The first ring part 212a

The first reflecting part 213a

The second capping body 22a

The second flat part 220a

The second opening 221a

The second ring part 222a

The light emitting module 3a first substrate 30a

The first luminescence component 31a

The first reflecting layer 32a

Transparent enclosure colloid 4a

The first light La

Electric wire Pa

(second embodiment)

Hollow light guide body 10b

The second capping body 22b, the second flat part 220b

The second opening 221b

The second ring part 222b

(the 3rd embodiment)

Hollow light guide body 10c annular groove 100c

The first luminescence component 31c

Transparent enclosure colloid 4c

(the 4th embodiment)

Hollow light guide body 10d annular groove 100d

The first luminescence component 31d

Transparent enclosure colloid 4d

(the 5th embodiment)

Hollow light guide body 10e annular groove 100e

The first luminescence component 31e

Transparent enclosure colloid 4e

(the 6th embodiment)

Hollow light guide body 10f

Reflectance coating 11f

The first substrate 30f

The first luminescence component 31f

Light emitting module 3f ' second substrate the 30f '

The second luminescence component 31f '

The second reflecting layer 32f '

The first capping body 21f

The second capping body 22f, the second flat part 220f

The second ring part 222f

The second reflecting part 223f

Transparent enclosure colloid 4f '

The first light Lf

The second light Lf '

Electric wire Pf

(the 7th embodiment)

Hollow light guide body 10g spread powder 100g

The first light Lg

The second light Lg '

(the 8th embodiment)

Light guide module 1h hollow light guide body 10h

Light guide body 101h

Light guide body 102h

(the 9th embodiment)

Light guide module 1i hollow light guide body 10i

Light guide body 101i

Light guide body 102i

Light guide body 103i

The specific embodiment

See also shown in Figure 1A to Fig. 1 C, Figure 1A has the three-dimensional exploded view of first embodiment of the ray structure of annular illumination effect for the present invention; Figure 1B has the three-dimensional combination figure of first embodiment of the ray structure of annular illumination effect for the present invention; Fig. 1 C is the 1C-1C profile of Figure 1B of the present invention.By among above-mentioned these figure as can be known, first embodiment of the invention provides a kind of ray structure with annular illumination effect, it comprises: a light guide module 1a, a capping module 2a, a light emitting module 3a and a transparent enclosure colloid 4a.

Wherein, this light guide module 1a has the reflectance coating 11a that a hollow light guide body 10a and forms in the inner surface of this hollow light guide body 10a, and this hollow light guide body 10a and this reflectance coating 11a can make by the mode of extra quality injection molding (double injection molding), coating (coating) or spraying (spraying).This hollow light guide body 10a can be the arbitrary shape cylinder of hollow, for example hollow circular cylinder, hollow square body, hollow triangulo column or the polygonal cylinder of hollow etc., and the hollow shape in this hollow light guide body 10a also can be arbitrary shape, for example cylindrical, square column type, triangle cylindricality or polygonal cylindricality etc.With first embodiment, this hollow light guide body 10a is a hollow circular cylinder, and the hollow shape in this hollow light guide body 10a is cylindrical.

Moreover, this capping module 2a has the second capping body 22a that first a capping body 21a and who is arranged at the side of this hollow light guide body 10a is arranged at another opposite side of this hollow light guide body 10a, and this first capping body 21a and this second capping body 22a are all made by non-light-transmitting materials.

In addition, this first capping body 21a has the first opening 211a, that one first flat part 210a, runs through this first flat part 210a and is arranged at the first ring part 212a on this first flat part 210a, and first a reflecting part 213a who is formed at the inner surface of this first ring part 212a, and shown in Figure 1B and Fig. 1 C, this first capping body 21a surrounds the mode of an end of this hollow light guide body 10a with on the end that is fixed in this hollow light guide body 10a by this first ring part 212a.

In addition, this second capping body 22a has the second opening 221a, and the second ring part 222a who is arranged on this second flat part 220a that one second flat part 220a, runs through this second flat part 220a, and shown in Figure 1B and Fig. 1 C, this second capping body 22a surrounds the mode of another end opposite of this hollow light guide body 10a to be fixed in another end opposite of this hollow light guide body 10a by this second ring part 222a.

Moreover, this light emitting module 3a has one first substrate 30a, a plurality of first luminescence component 31a and one first reflecting layer 32a, wherein this first substrate 30a can be a circuit board (this circuit board can connect an electric wire Pa, and this electric wire Pa can pass this first opening 211a and be connected to a power supply; Perhaps, this circuit board has the function that solar energy is converted to electric energy, to provide these first luminescence components 31a required electric power), these first luminescence components 31a is arranged on this first substrate 30a all electrically, and this first reflecting layer 32a is formed between last these the first luminescence components 31a of reaching of this first substrate 30a.Yet, above-mentioned these first luminescence components 31a differs and is decided to be point source of light (pointlight source), for example an annulus fluorescent layer (figure does not show) can be covered on a plurality of luminescence chips (figure does not show), so that these luminescence chips produce an annular light source (annular lightsource) by this fluorescence coating in advance.In addition, the color of the color of this hollow light guide body 10a and above-mentioned these first luminescence component light that 31a produces also can be along with user's user demand is changed or adjusted.

Shown in Fig. 1 C, this light emitting module 3a is placed in this first capping body 21a, therefore these first luminescence components 31a is positioned at the top of this first flat part 210a and is surrounded by this first ring part 212a, and these first luminescence components 31a is between this hollow light guide body 10a and this first capping body 21a.In addition, by the cooperation of this first reflecting part 213a and this first reflecting layer 32a, so that the light that these first luminescence components 31a is produced can be reflected onto this hollow light guide body 10a effectively.

In addition, this transparent enclosure colloid 4a is filled between the wherein side surface and these first luminescence components 31a of this hollow light guide body 10a.Therefore, not having any air between the wherein side surface of this hollow light guide body 10a and these first luminescence components 31a produces, so the present invention is by the use of this transparent enclosure colloid 4a, the light loss in the time of can effectively reducing these first luminescence components 31a throw light to this hollow light guide body 10a.

For this reason, the first light L a that these first luminescence components 31a is produced invests this hollow light guide body 10a, and because this hollow light guide body 10a can be made by transparent material, so this first light L a is by the guiding of this hollow light guide body 10a and the reflection of this reflectance coating 11a, so that this hollow light guide body 10a produces the illumination effect of annular.

See also shown in Fig. 2 A to Fig. 2 B, wherein Fig. 2 A ray structure schematic perspective view of the second capping body in a second embodiment of having an annular illumination effect for the present invention; Fig. 2 B has the side cutaway view of second embodiment of the ray structure of annular illumination effect for the present invention.By among above-mentioned these figure as can be known, the difference of the second embodiment of the invention and the first embodiment maximum is: in a second embodiment, one second capping body 22b has the second opening 221b, and the second ring part 222b who is arranged on this second flat part 220b that one second flat part 220b, runs through this second flat part 220b, and shown in Fig. 2 B, this second capping body 22b is fastened in mode in the end of a hollow light guide body 10b with on the end that is fixed in this hollow light guide body 10b by this second ring part 222b.

See also shown in Fig. 3 A to Fig. 3 B, wherein Fig. 3 A has the three-dimensional exploded view of the 3rd embodiment of the ray structure of annular illumination effect for the present invention; Fig. 3 B has the generalized section of the 3rd embodiment of the ray structure of annular illumination effect for the present invention.By among above-mentioned these figure as can be known, the difference of the third embodiment of the invention and the first embodiment maximum is: in the 3rd embodiment, the wherein side surface of one hollow light guide body 10c has an annular groove 100c, and a plurality of first luminescence component 31c is placed in this annular groove 100c.In addition because this annular groove 100c be shaped as annular so, so one be placed in this annular groove 100c to be filled in the annular that is shaped as of transparent enclosure colloid 4c between these first luminescence component 31c and this annular groove 100c.

See also shown in Figure 4ly, it has the generalized section of the 4th embodiment of the ray structure of annular illumination effect for the present invention.By among the above-mentioned figure as can be known, the difference of fourth embodiment of the invention and the 3rd embodiment maximum is: in the 4th embodiment, the wherein side surface of one hollow light guide body 10d has the annular groove 100d that a bottom surface is V-shape, and a plurality of first luminescence component 31d is placed in this annular groove 100d.In addition because the bottom shape of this annular groove 100d to be V-shape so, so a bottom shape that is placed in this annular groove 100d to be filled in the transparent enclosure colloid 4d between these first luminescence component 31d and this annular groove 100d is a V-shape.

See also shown in Figure 5ly, it has the three-dimensional exploded view of the 5th embodiment of the ray structure of annular illumination effect for the present invention.By among the above-mentioned figure as can be known, the difference of fifth embodiment of the invention and the 3rd embodiment maximum is: in the 5th embodiment, the wherein side surface of one hollow light guide body 10e has the annular groove 100e of a plurality of corresponding a plurality of first luminescence components, and a plurality of first luminescence component 31e is placed in respectively in this annular groove 100e.In addition, because distinctly separate square that be shaped as of these annular grooves 100e died, so a plurality of interior 100e of these annular grooves that is placed in respectively is all square with the shape that is filled in the transparent enclosure colloid 4e between each first luminescence component 31e and each the annular groove 100e respectively.

See also shown in Fig. 6 A to Fig. 6 B, wherein Fig. 6 A has the three-dimensional exploded view of the 6th embodiment of the ray structure of annular illumination effect for the present invention; Fig. 6 B has the generalized section of the 6th embodiment of the ray structure of annular illumination effect for the present invention.By among above-mentioned these figure as can be known, the difference of the sixth embodiment of the invention and the first embodiment maximum is: the 6th embodiment provides another light emitting module 3f ', it comprises: one second substrate 30f ', a plurality of second luminescence component 31f ' and one second reflecting layer 32f ', wherein this second substrate 30f ' can be a circuit board, these second luminescence components 31f ' is arranged on this second substrate 30f ' all electrically, and this second reflecting layer 32f ' is formed on this second substrate 30f ' and reaches between these second luminescence components 31f '.

Shown in Fig. 6 B, this light emitting module 3f ' is placed in the one second capping body 22f, therefore these second luminescence components 31f ' is positioned at the top of this second flat part 220f and is surrounded by this second ring part 222f, and these second luminescence components 31f ' is between this hollow light guide body 10f and this second capping body 22f.In addition, by the cooperation of this second reflecting part 223f and this second reflecting layer 32f ', so that the light that these second luminescence components 31f ' is produced can be reflected onto this hollow light guide body 10f effectively.

In addition, another transparent enclosure colloid 4f ' is filled between the wherein side surface and these second luminescence components 31f ' of this hollow light guide body 10f.Therefore, not having any air between the wherein side surface of this hollow light guide body 10f and these second luminescence components 31f ' produces, so the present invention is by the use of this transparent enclosure colloid 4f ', the light loss in the time of can effectively reducing these second luminescence component 31f ' throw lights to this hollow light guide body 10f.

In addition, one first substrate 30f and this second substrate 30f ' can pass through an electric wire Pf mutual conduction, and this electric wire P f passes the hollow region in this hollow light guide body 10f, guide away and are connected to a power supply from one first capping body 21f at last.So electric wire Pf of the present invention is contained in the hollow region in this hollow light guide body 10f, therefore can produce the problem that electric wire Pf exposes, and then reach whole aesthetic.

For this reason, the first light Lf that these first luminescence components 31f is produced invests this hollow light guide body 10f, and because this hollow light guide body 10f can be made by transparent material, so this first light Lf is by the guiding of this hollow light guide body 10f and the reflection of this reflectance coating 11f, so that this hollow light guide body 10f produces the illumination effect of annular.Moreover, this hollow light guide body of second light Lf ' trend of purchasing 10f that these second luminescence components 31f ' is produced, and because this hollow light guide body 10f can be made by transparent material, so this second light Lf ' is by the guiding of this hollow light guide body 10f and the reflection of this reflectance coating 11f, so that this hollow light guide body 10f produces the illumination effect of annular.

See also shown in Figure 7ly, it has the generalized section of the 7th embodiment of the ray structure of annular illumination effect for the present invention.By among the above-mentioned figure as can be known, the difference of seventh embodiment of the invention and the 6th embodiment maximum is: in the 7th embodiment, the inside of one hollow light guide body 10g adds 5/1000ths to centesimal spread powder 100g, so that this hollow light guide body 10g (for example: add spread powder injection molding again in acryl presents vaporific effect, make the acryl of otherwise transparent present vaporific effect, to reach the uniform effect of illumination), and the first light Lg and the second light Lg ' are presented on the surface of this hollow light guide body 10g equably, so that this hollow light guide body 10g uses as a lamp source.Therefore, the present invention not only can be used as lighting apparatus and use (for example first embodiment to the, six embodiment), and the present invention uses (for example the 7th embodiment) in the lamp source that also can be used as.

See also shown in Figure 8ly, it is the perspective exploded view of the 8th embodiment of light guide module of the present invention.By among the above-mentioned figure as can be known, a light guide module 1h has a hollow light guide body 10h, and this hollow light guide body 10h is made up of two light guide body (101h, 102h).

See also shown in Figure 9ly, it is the perspective exploded view of the 9th embodiment of light guide module of the present invention.By among the above-mentioned figure as can be known, a light guide module 1i has a hollow light guide body 10i, and this hollow light guide body 10i is made up of three light guide body (101i, 102i, 103i).

By above-mentioned Fig. 8 and Fig. 9 as can be known, the hollow light guide body of any embodiment of the present invention can be made up of the polylith light guide body.Therefore; disclosed two light guide body of Fig. 8 and disclosed three light guide body of Fig. 9 just are used for for example; the hollow light guide body of forming by a complete light guide body or so long as the hollow light guide body of being made up of the light guide body more than two is all the category that the present invention protects for example.

Moreover with light emitting module, light emitting module of the present invention can be following two kinds of forms:

One, light emitting module of the present invention can be made up of many rows luminescence component row (light-emitting row), and wherein each row's luminescence component row has a plurality of blue led chips (blue LED chip) and at least one emitting red light two luminescence chips (red LED chip).In addition, cover one deck wavelength conversion layer on each blue led chips, changing the wavelength that these blue led chips are emitted, and cover one deck photic zone on each emitting red light two luminescence chip.Change the blue led chips of its emission wavelength and the mixed light effect of these emitting red lights two luminescence chips by these because of wavelength conversion layer, to produce the white light source of high color rendering (color rendering index).

Wherein, wherein one deck in these wavelength conversion layers is a fluorescent orange powder (orange phosphorpowder) and the mixing of packing colloid (package colloid), and it is used for making that wherein a blue led chips produces the projection source of peak luminous wavelength scope between 595～610nm.Part in these wavelength conversion layers is a green emitting phosphor (green phosphor powder) and the mixing of packing colloid (package colloid), and it is used to make the corresponding blue led chips of part to produce the projection source of peak luminous wavelength scope between " between 480～495nm " or " between 520～540nm ".Part in these wavelength conversion layers is a yellow fluorescent powder (yellow phosphor powder) and the mixing of packing colloid (package colloid), it is used to make the corresponding blue led chips of part to produce colour temperature between 7000～11, the projection source between the 000K.In addition, the fluorescent material (orange and green phosphor powder) of the orange and green mixing of the replaceable one-tenth of above-mentioned yellow fluorescent powder, and fluorescent material of this orange and green mixing and packing colloid (package colloid) be mixed for make corresponding first luminescence chip of another part produce to have the projection source of predetermined colour temperature (color temperature).These second luminescence chips each other alternately (alternatively) luminescence components of being separately positioned on different rows list.

Two, the Yellow luminous chipset that covered by the photic zone group of the green emitting chipset that covered by the photic zone group of the light emitting module of the present invention emitting red light chipset that can be covered by the photic zone group by a blue-light-emitting chipset that is covered by the wavelength conversion layer group,,,, and an amber luminescence chip group that is covered by the photic zone group formed.The mutual mixed light of the light source that is sent by these luminescence chip groups is so that array type light emitting module of the present invention can blend the white light source of high color rendering (color rendering index).

In addition, above-mentioned wavelength conversion layer group comprises following four kinds of hybrid modes at least:

First kind: this wavelength conversion layer group is a yellow fluorescent powder (yellow phosphor powder) and the mixing of packing colloid (package colloid), and it is used to make light source that this blue-light-emitting chipset projected to convert the projection source of colour temperature (color temperature) scope between 2800～10000K to by the absorption of this wavelength conversion layer group.

Second kind: the fluorescent material that this wavelength conversion layer group is orange and green mixing (orange and greenfluorescent powder) mixes with packing colloid (package colloid), and it is used to make light source that this blue-light-emitting chipset projected to convert the projection source of colour temperature (colortemperature) scope between 2800～10000K to by the absorption of this wavelength conversion layer group.

The third: this wavelength conversion layer group is made up of multilayer first wavelength conversion layer (firstwavelength-converting layer) and second wavelength conversion layer (second wavelength-convertinglayer), these first wavelength conversion layers are yellow fluorescent powder (yellow phosphor powder) and the mixing of packing colloid (package colloid), it is used to make light source that this blue-light-emitting chipset projected to convert the projection source of colour temperature (color temperature) scope between 2800～10000K to by the absorption of these first wavelength conversion layers, and these second wavelength conversion layers are green emitting phosphor (green phosphor powder) and the mixing of packing colloid (package colloid), and it is used to make light source that this blue-light-emitting chipset projected to convert the projection source of peak luminous wavelength scope between 480～495nm to by the absorption of this second wavelength conversion layer.

The 4th kind: this wavelength conversion layer group is made up of multilayer first wavelength conversion layer (firstwavelength-converting layer) and second wavelength conversion layer (second wavelength-convertinglayer), the fluorescent material that these first wavelength conversion layers are orange and green mixing (orange andgreen fluorescent powder) mixes with packing colloid (package colloid's), it is used to make light source that this blue-light-emitting chipset projected to convert the projection source of colour temperature (color temperature) scope between 2800～10000K to by the absorption of these first wavelength conversion layers, and these second wavelength conversion layers are green emitting phosphor (green phosphor powder) and the mixing of packing colloid (packagecolloid), and it is used to make light source that this blue-light-emitting chipset projected to convert the projection source of peak luminous wavelength scope between 480～495nm to by the absorption of this second wavelength conversion layer.

Certainly; the present invention also can have other various embodiments; under the situation that does not deviate from spirit of the present invention and essence thereof; those of ordinary skill in the art work as can make various corresponding changes and distortion according to the present invention, but these corresponding changes and distortion all should belong to the protection domain of the appended claim of the present invention.

Claims (20)

1, a kind of ray structure with annular illumination effect is characterized in that, comprising:

One light guide module, it has the reflectance coating that a hollow light guide body and forms in the inner surface of this hollow light guide body;

One capping module, it has the second capping body that first a capping body and that is arranged at a side of this hollow light guide body is arranged at another opposite side of this hollow light guide body; And

One light emitting module, it has a plurality of first luminescence components that are arranged between this hollow light guide body and this first capping body;

For this reason, first light that these first luminescence components are produced is invested this hollow light guide body, and this first light is by the guiding of this hollow light guide body and the reflection of this reflectance coating, so that this hollow light guide body produces the illumination effect of annular.

2, the ray structure with annular illumination effect according to claim 1, it is characterized in that, this hollow light guide body is transparent material spare or constitutes part by transparent material and spread powder made from mixed materials, and this hollow light guide body comprises one or more light guide body.

3, the ray structure with annular illumination effect according to claim 1 is characterized in that, a wherein side surface of this hollow light guide body has an annular groove, and these first luminescence components are placed in this annular groove.

4, the ray structure with annular illumination effect according to claim 3 is characterized in that, also further comprises: one is placed in this annular groove to be filled in the transparent enclosure colloid between these first luminescence components and this annular groove.

5, the ray structure with annular illumination effect according to claim 1, it is characterized in that, a wherein side surface of this hollow light guide body has the annular groove of a plurality of corresponding these first luminescence components, and these first luminescence components are placed in respectively in these annular grooves.

6, the ray structure with annular illumination effect according to claim 5, it is characterized in that, also further comprise: a plurality of being placed in respectively in these annular grooves to be filled in the transparent enclosure colloid between each first luminescence component and each annular groove respectively.

7, the ray structure with annular illumination effect according to claim 1 is characterized in that, also further comprises: be filled in a wherein side surface of this hollow light guide body and the transparent enclosure colloid between these first luminescence components.

8, the ray structure with annular illumination effect according to claim 1 is characterized in that, this first capping body and this second capping body are all non-light-transmitting materials part.

9, ray structure with annular illumination effect according to claim 1, it is characterized in that, this first capping body has one first flat part, one runs through first opening of this first flat part, one is arranged at first ring part on this first flat part, and first reflecting part that is formed at the inner surface of this first ring part, these first luminescence components are arranged at the top of this first flat part and are surrounded by this first ring part, and this first capping body surrounds the mode of an end of this hollow light guide body with on the end that is fixed in this hollow light guide body by this first ring part.

10, the ray structure with annular illumination effect according to claim 1, it is characterized in that, this second capping body has second opening, and second ring part that is arranged on this second flat part that one second flat part, runs through this second flat part, and this second capping body surrounds the mode of an end of this hollow light guide body with on the end that is fixed in this hollow light guide body by this second ring part.

11, the ray structure with annular illumination effect according to claim 1, it is characterized in that, this second capping body has second opening, and second ring part that is arranged on this second flat part that one second flat part, runs through this second flat part, and this second capping body is fastened in mode in the end of this hollow light guide body with on the end that is fixed in this hollow light guide body by this second ring part.

12, the ray structure with annular illumination effect according to claim 1, it is characterized in that: this light emitting module has one first substrate and and is formed at first reflecting layer that reaches on this first substrate between these first luminescence components, and these first luminescence components are arranged on this first substrate all electrically.

13, the ray structure with annular illumination effect according to claim 1 is characterized in that, also further comprises: another light emitting module, it has a plurality of second luminescence components that are arranged between this hollow light guide body and this second capping body.

14, the ray structure with annular illumination effect according to claim 13, it is characterized in that: this light emitting module has one second substrate and and is formed at second reflecting layer that reaches on this second substrate between these second luminescence components, and these second luminescence components are arranged on this second substrate all electrically.

15, the ray structure with annular illumination effect according to claim 13 is characterized in that: a wherein side surface of this hollow light guide body have one the annular recessed, and these second luminescence components be placed in this annular recessed in.

16, the ray structure with annular illumination effect according to claim 15 is characterized in that, also further comprises: one be placed in this annular recessed in to be filled in the transparent enclosure colloid between these second luminescence components and this annular groove.

17, the ray structure with annular illumination effect according to claim 13, it is characterized in that: a wherein side surface of this hollow light guide body has the annular groove of a plurality of corresponding these second luminescence components, and these second luminescence components are placed in respectively in these annular grooves.

18, the ray structure with annular illumination effect according to claim 17, it is characterized in that, also further comprise: a plurality of being placed in respectively in these annular grooves to be filled in the transparent enclosure colloid between each second luminescence component and each annular groove respectively.

19, the ray structure with annular illumination effect according to claim 13 is characterized in that, also further comprises: be filled in a wherein side surface of this hollow light guide body and the transparent enclosure colloid between these second luminescence components.

20, ray structure with annular illumination effect according to claim 13, it is characterized in that: this second capping body has one second flat part, one runs through second opening of this second flat part, one is arranged at second ring part on this second flat part, and second reflecting part that is formed at the inner surface of this second ring part, these second luminescence components are arranged on this second flat part and by this second ring part and surround, and this second capping body surrounds the mode of an end of this hollow light guide body with on the end that is fixed in this hollow light guide body by this second ring part.

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