CN2618185Y - Scattering arrangement of light guiding panel of background module - Google Patents

Abstract

The utility model relates to a scattering arrangement structure of light guide plate of backlighting module, which comprises a light guide plate, a light source arranged on the side of the light guide plate to emit lights into the light guide plate, a light-reflecting cover encompassing the light source used outside to reflect lights, and a plurality of scattering structures heaved inside the bottom of the light guide plate or protruded out of the bottom of the light guide plate used to damage the total reflection of lights to reflect lights to the surface of the light guide plate; wherein, the scattering structures heaved or protruded out of the bottom of the light guide plate from the light source from shallow to deep sideward the opposite direction of the light source, or protruded out of the bottom of the light guide plate from the light source from deep to shallow sideward the opposite direction of the light source, or heaved or protruded out of the bottom of the light guide plate from the light source uncertain sideward the opposite direction of the light source.

Description

Backlight modular unit light guide plate scattering arrangement architecture

Technical field

The utility model relates to a kind of design of light guide plate, especially is a kind of design of scattering arrangement architecture of light guide plate.

Background technology

The display device of liquid crystal panel must have the backlight modular unit as display device, and backlight modular unit must satisfy the needed brightness of display frame, brightness uniformity and visual angle (penetrating light orientation angle) aspect optics; At concerned power, backlight modular unit must satisfy low consumption electric power and low noise requirement.According to structure backlight, full run-down type and the side light type of being broadly divided into backlight, wherein full run-down type is to dispose light source under liquid crystal panel, the irradiating liquid crystal panel, side light type then is to dispose light guide plate under liquid crystal panel, and at the edge of light guide plate configuration light source, the ejaculation optical illumination liquid crystal panel that scatters with light guide plate.

Generally speaking, light guide plate is by flat boards that transparent plastic constituted such as acrylic resins, the shape of light guide plate can be a parallel-plate, a clapboard or a pair of clapboard, be injected into the light beam of light guide plate from light guide plate side light source, refringence by light guide plate and air, carry out total reflection repeatedly, in the light guide plate internal transmission, the critical angle of total reflection is about 42 degree, and the diffusing structure in the light guide plate, to utilize light beam to pass through the characteristic of diffusing structure back reflection angle exactly, so that beam reflection is penetrated by the light guide plate surface less than the cirtical angle of total reflection.

As shown in Figure 1, it is the side view of the backlight modular unit light guide plate diffusing structure of a prior art, this backlight modular unit comprises a light source 114, one light reflecting cover 112, the diffusing structure 116 that one light guide plate 118 is identical with a plurality of depths, the design of light guide plate diffusing structure traditionally, as U.S. Patent number US 5,703, the base area size of the change diffusing structure of mentioning in 667 116 is to obtain uniform luminosity output, or as U.S. Patent number US 6,123, in 431, the spacing that changes diffusing structure 116 is to obtain required light output, but this dual mode does not have good obstructing capacity for the light of injecting with directional light in the light guide plate 118, and then cause the waste of the energy, therefore just need a kind ofly directional light to be reflexed to the diffusing structures of light guide plate 118 surface outputs and equably with the diffusing structure of light reflection by the output of light guide plate surface.

Summary of the invention

Fundamental purpose of the present utility model is to provide the light guide plate scattering arrangement architecture of backlight modular unit, this structure is for utilizing the depth that changes diffusing structure, adjust the total reflecting destructive ability in the light guide plate, the light that makes the backlight modular unit of side light type obtain required brightness is evenly exported, and strengthens whole energy use efficiency and promotes the briliancy performance.

The technical scheme that the utility model adopted is with a kind of backlight modular unit, comprise light guide plate, the side that is installed on light guide plate is to launch light into the light source in this light guide plate, ambient light source outer in order to reflection ray light reflecting cover and swell in the bottom surface of light guide plate or protrude in outside the bottom surface of light guide plate in order to the total reflection that destroys light light is reflexed to a plurality of diffusing structures on this light guide plate surface, these a plurality of diffusing structures from shallow to deep by light source side toward light source reverse direction protuberance or protrude in bottom surface of light guide plate, or these a plurality of diffusing structures protrude in bottom surface of light guide plate by being deep to shallowly by light source side toward the light source reverse direction, also or these a plurality of diffusing structure depths erratically by light source side toward light source reverse direction protuberance or protrude in bottom surface of light guide plate.

Description of drawings

Fig. 1 is the light guide plate side view of the diffusing structure that a same intervals and the identical depth are arranged in the prior art;

Fig. 2 A be one comprise with a same intervals from light source side toward the light source reverse direction from shallow to deep ground swell arise from the parallel conductive tabula rasa side view of the tool one side light source of the diffusing structure in the bottom surface of light guide plate;

Fig. 2 B be one comprise with a same intervals from light source side toward the light source reverse direction from shallow to deep ground swell arise from the parallel conductive tabula rasa side view in the tool bilateral marginal ray source of the diffusing structure in the bottom surface of light guide plate;

Fig. 2 C one comprises with a same intervals and swells the parallel conductive tabula rasa side view in tool bilateral marginal ray source of the diffusing structure in bottom surface of light guide plate from light source side toward the light source reverse direction depth erratically;

Fig. 2 D be one comprise with a same intervals from light source side toward the light source reverse direction from shallow to deep ground swell arise from the wedge shape light guide plate side view of the tool one side light source of the diffusing structure in the bottom surface of light guide plate;

Fig. 2 E be one comprise with a same intervals from light source side toward the light source reverse direction from shallow to deep ground swell arise from the double-wedge light guide plate side view in the tool bilateral marginal ray source of the diffusing structure in the bottom surface of light guide plate;

Fig. 2 F one comprises with a same intervals and swells the double-wedge light guide plate side view in tool bilateral marginal ray source of the diffusing structure in bottom surface of light guide plate from light source side toward the light source reverse direction depth erratically;

Fig. 3 A one comprises with a same intervals and protrudes in the parallel conductive tabula rasa side view of the tool one side light source of the diffusing structure outside the bottom surface of light guide plate from light source side toward the light source reverse direction from shallow to deep;

Fig. 3 B one comprises with a same intervals and protrudes in the parallel conductive tabula rasa side view in the tool bilateral marginal ray source of the diffusing structure outside the bottom surface of light guide plate from light source side toward the light source reverse direction from shallow to deep;

Fig. 3 C one comprises with a same intervals and protrudes in the parallel conductive tabula rasa side view in the tool bilateral marginal ray source of the diffusing structure outside the bottom surface of light guide plate from light source side toward the light source reverse direction depth erratically;

Fig. 3 D one comprises with a same intervals and protrudes in the wedge shape light guide plate side view of the tool one side light source of the diffusing structure outside the bottom surface of light guide plate from light source side toward the light source reverse direction from shallow to deep;

Fig. 3 E one comprises with a same intervals and protrudes in the double-wedge light guide plate side view in the tool bilateral marginal ray source of the diffusing structure outside the bottom surface of light guide plate from light source side toward the light source reverse direction from shallow to deep;

Fig. 3 F one comprises with a same intervals and protrudes in the double-wedge light guide plate side view in the tool bilateral marginal ray source of the diffusing structure outside the bottom surface of light guide plate from light source side toward the light source reverse direction depth erratically;

Fig. 4 A be one comprise with a same intervals from light source side toward the light source reverse direction by the parallel conductive tabula rasa side view that is deep to the tool one side light source that protrudes in the diffusing structure outside the bottom surface of light guide plate shallowly;

Fig. 4 B one comprises with a same intervals from light source side toward the light source reverse direction by the parallel conductive tabula rasa side view in the tool bilateral marginal ray source that is deep to the diffusing structure that protrudes in outside the bottom surface of light guide plate shallowly;

Fig. 4 C be one comprise with a same intervals from light source side toward the light source reverse direction by the wedge shape light guide plate side view that is deep to the tool one side light source that protrudes in the diffusing structure outside the bottom surface of light guide plate shallowly;

Fig. 4 D one comprises with a same intervals from light source side toward the light source reverse direction by the double-wedge light guide plate side view in the tool bilateral marginal ray source that is deep to the diffusing structure that protrudes in outside the bottom surface of light guide plate shallowly;

Fig. 5 one has the decomposing schematic representation of the LCD of a side light type backlight modular unit;

Fig. 6 one has a liquid crystal indicator decomposing schematic representation of LCD shown in Figure 5;

Fig. 7 A is a LCD side view, light guide plate wherein be one comprise with a same intervals from light source side toward the light source reverse direction from shallow to deep ground swell arise from the parallel conductive tabula rasa in the tool bilateral marginal ray source of the diffusing structure in the bottom surface of light guide plate;

Fig. 7 B is a LCD side view, and light guide plate wherein is one to comprise with a same intervals and swell the parallel conductive tabula rasa in tool bilateral marginal ray source of the diffusing structure in bottom surface of light guide plate from light source side toward the light source reverse direction depth erratically;

Fig. 7 C is a LCD side view, light guide plate wherein be one comprise with a same intervals from light source side toward the light source reverse direction from shallow to deep ground swell arise from the double-wedge light guide plate in the tool bilateral marginal ray source of the diffusing structure in the bottom surface of light guide plate;

Fig. 7 D is a LCD side view, and light guide plate wherein is one to comprise with a same intervals and swell the double-wedge light guide plate in tool bilateral marginal ray source of the diffusing structure in bottom surface of light guide plate from light source side toward the light source reverse direction depth erratically;

Fig. 7 E is a LCD side view, and light guide plate wherein is one to comprise with a same intervals and protrude in the parallel conductive tabula rasa in the tool bilateral marginal ray source of the diffusing structure outside the bottom surface of light guide plate from light source side toward the light source reverse direction from shallow to deep;

Fig. 7 F is a LCD side view, and light guide plate wherein is one to comprise with a same intervals and protrude in the parallel conductive tabula rasa in the tool bilateral marginal ray source of the diffusing structure outside the bottom surface of light guide plate from light source side toward the light source reverse direction depth erratically;

Fig. 7 G is a LCD side view, and light guide plate wherein is one to comprise with a same intervals and protrude in the double-wedge light guide plate in the tool bilateral marginal ray source of the diffusing structure outside the bottom surface of light guide plate from light source side toward the light source reverse direction from shallow to deep;

Fig. 7 H is a LCD side view, and light guide plate wherein is one to comprise with a same intervals and protrude in the double-wedge light guide plate in the tool bilateral marginal ray source of the diffusing structure outside the bottom surface of light guide plate from light source side toward the light source reverse direction depth erratically;

Fig. 7 I is a LCD side view, and light guide plate wherein is one to comprise with a same intervals from light source side toward the light source reverse direction by the parallel conductive tabula rasa in the tool bilateral marginal ray source that is deep to the diffusing structure that protrudes in outside the bottom surface of light guide plate shallowly; And

Fig. 7 J is a LCD side view, and light guide plate wherein is one to comprise with a same intervals from light source side toward the light source reverse direction by the double-wedge light guide plate in the tool bilateral marginal ray source that is deep to the diffusing structure that protrudes in outside the bottom surface of light guide plate shallowly.

Symbol description among the figure

12 light reflecting covers

112 light reflecting covers

14 light sources

114 light sources

16 diffusing structures

116 diffusing structures

18 light guide plate

118 light guide plate

20 reflecting piece

200 first frameworks

201 screws

21 protective sheet

210 second frameworks

211 screws

22 prismatic lenses

220 bolts

24 diffusion sheets

28 liquid crystal panels

30 side light type backlight modular units

40 display panels

50 LCD

500 back housing

510 screws

512 bolts

520 front housings

Embodiment

Embodiment more of the present utility model can be described in detail as follows.Yet, except describing in detail, the utility model can also be widely at other embodiment.That is, the restriction of the embodiment that scope of the present utility model is not subjected in this proposition, and should be as the criterion with the claim that is proposed.

A preferred embodiment is shown in Fig. 2 A～F in the utility model, a backlight modular unit tool one light guide plate 18, one or a plurality of light source 14 be positioned at light guide plate 18 sides, one or a plurality of light reflecting cover 12 be covered in one or a plurality of light source 14 outsides and a plurality of diffusing structure 16 swell in the bottom surface of light guide plate 18.

Shown in Fig. 2 A, a plurality of diffusing structures 16 with a same intervals from light source 14 sides toward light source 14 reverse directions from shallow to deep ground swell arise from the bottom surface in the light guide plate 18, these a plurality of diffusing structures 16 can be when light guide plate 18 be shaped, be formed on the bottom surface in the light guide plate 16 or boring back formation on the bottom surface in light guide plate 16, these a plurality of diffusing structures 16 with fixed intervals from shallow to deep ground swell arise from the bottom surface in the light guide plate 18, the arrangement of a plurality of diffusing structures 16 like this can reflective distance than light source 14 be directional light far away and destroy the total reflection of light light guide plate 18 in with the light reflection from the even ejaculations in light guide plate 18 surfaces.

Shown in Fig. 2 B, be that with the difference of Fig. 2 A this is the backlight modular unit in a tool bilateral marginal ray source 14, a plurality of diffusing structures 16 by light guide plate 18 both sides from shallow to deep toward light guide plate 18 central uplifts; And the difference of Fig. 2 C and Fig. 2 B is for considering the distribution of light source 14 intensity, a plurality of diffusing structures 16 will with the indefinite mode of the depth swell bottom surface in light guide plate 18 in reflection ray equably from light guide plate 18 surface ejaculations; Fig. 2 D～F and Fig. 2 A～C are similar, main between the two difference is the profile of light guide plate 18, the light guide plate 18 of Fig. 2 A～C is a parallel conductive tabula rasa, and Fig. 2 D is a wedge shape light guide plate, Fig. 2 E～F is a double-wedge light guide plate, in Fig. 2 D～E a plurality of diffusing structures 16 by light guide plate 18 light sources 14 sides from shallow to deep ground swell arise from the bottom surface in the light guide plate 18, and in Fig. 2 F, a plurality of diffusing structures 16 are arised from the bottom surface in the light guide plate 18 by the deep mixed ground swell of light guide plate 18 light sources, 14 sides.

Another preferred embodiment is shown in Fig. 3 A～F in the utility model, a backlight modular unit tool one light guide plate 18, one or a plurality of light source 14 be positioned at light guide plate 18 sides, one or a plurality of light reflecting cover 12 be covered in one or a plurality of light source 14 outsides and a plurality of diffusing structure 16 protrude in outside the bottom surface of light guide plate 18.

As shown in Figure 3A, a plurality of diffusing structures 16 protrude in outside the bottom surface of light guide plate 18 toward light source 14 reverse directions from light source 14 sides from shallow to deep with a same intervals, these a plurality of diffusing structures 16 can be formed at the outer or formation again after the boring of the bottom surface of light guide plate 16 in bottom surface of light guide plate 16 when light guide plate 18 is shaped, these a plurality of diffusing structures 16 protrude in from shallow to deep with fixed intervals outside the bottom surface of light guide plate 18, and the arrangement of a plurality of diffusing structures 16 like this can destroy the total reflection of light in light guide plate 18 so that the light reflection is evenly penetrated from light guide plate 18 surfaces.

Shown in Fig. 3 B, be that with the difference of Fig. 3 A this is the backlight modular unit in a tool bilateral marginal ray source 14, a plurality of diffusing structures 16 by light guide plate 18 both sides from shallow to deep toward light guide plate 18 central projections for outside light guide plate 18 bottom surfaces; And the difference of Fig. 3 C and Fig. 3 B is for considering the distribution of light source 14 intensity, and a plurality of diffusing structures 16 will protrude in reflection ray equably from light guide plate 18 surface ejaculations in the indefinite mode of the depth light guide plate the 18 bottom surface outside; Fig. 3 D～F and Fig. 3 A～C are similar, main between the two difference is the profile of light guide plate 18, the light guide plate 18 of Fig. 3 A～C is a parallel conductive tabula rasa, and Fig. 3 D is a wedge shape light guide plate, Fig. 3 E～F is a double-wedge light guide plate, a plurality of diffusing structures 16 are protruded in outside the bottom surface of light guide plate 18 from shallow to deep by light source 14 1 sides of light guide plate 18 in Fig. 3 D～E, and in Fig. 3 F, a plurality of diffusing structures 16 are protruded in outside the bottom surface of light guide plate 18 by light source 14 1 sides of light guide plate 18 deep mixedly.

Another preferred embodiment is shown in Fig. 4 A～D in the utility model, a backlight modular unit tool one light guide plate 18, one or a plurality of light source 14 be positioned at light guide plate 18 sides, one or a plurality of light reflecting cover 12 be covered in one or a plurality of light source 14 outsides and a plurality of diffusing structure 16 protrude in outside the bottom surface of light guide plate 18.

Shown in Fig. 4 A, a plurality of diffusing structures 16 with a same intervals from light source 14 1 sides toward light source 14 reverse directions by be deep to outside the bottom surface that protrudes in light guide plate 18 shallowly, these a plurality of diffusing structures 16 can be when light guide plate 18 be shaped, be formed at outside the bottom surface of light guide plate 16 or after the boring of the bottom surface of light guide plate 16 and form again, by be deep to outside the bottom surface that protrudes in light guide plate 18 shallowly, the arrangement of a plurality of diffusing structures 16 like this can destroy the total reflection of light in light guide plate 18 so that the light reflection is evenly penetrated from light guide plate 18 surfaces to these a plurality of diffusing structures 16 with fixed intervals.

Shown in Fig. 4 B, be that with the difference of Fig. 4 A this is the backlight modular unit in a tool bilateral marginal ray source 14, a plurality of diffusing structures 16 by light guide plate 18 both sides by being deep to shallowly toward light guide plate 18 central projections for outside light guide plate 18 bottom surfaces; Fig. 4 C～D and Fig. 4 A～category-B are seemingly, main between the two difference is the profile of light guide plate 18, the light guide plate 18 of Fig. 4 A～B is a parallel conductive tabula rasa, and Fig. 4 C is a wedge shape light guide plate, Fig. 4 D is a double-wedge light guide plate, in Fig. 4 C～D a plurality of diffusing structures 16 by light source 14 1 sides of light guide plate 18 by be deep to outside the bottom surface that protrudes in light guide plate 18 shallowly.

Side light type backlight modular unit of the present utility model can be used as the light emitting source of a LCD 50, as shown in Figure 5, LCD 50 decomposing schematic representations with a side light type backlight modular unit, wherein graphic too not complicated for making, some of side light type backlight modular unit are formed members, and for example light source 14 and light reflecting cover 12 are not shown among the figure through omitting, be arranged near a plurality of diffusing structures 16 in light guide plate 18 bottom surfaces and also be not shown in figure, LCD 50 (liquidcrystal display) structure that Fig. 5 shows comprises one first superimposed successively from the bottom to top framework 200, one reflecting piece 20, one light guide plate 18, one protective sheet 21 (protection sheet), one prismatic lens 22, one diffusion sheet 24, one liquid crystal panel 28 (liquid crystal panel) and one second framework 210.One side of first framework 200 has a plurality of screws 201, the same side of second framework 210 has the screw 201 that a plurality of screws 211 are aligned in first framework 200 equally, by fixture for example bolt 220 pass the screw 211 of second framework 210 and the screw 201 of first framework 200, with together with LCD 50 each component composition.Moreover, prismatic lens 22 concentrates in the angular field of view of LCD 50 in order to the emission light beam with light guide plate 18, to improve the luminosity of LCD 50, diffusion sheet 24 is in order to the emission beam spread with light guide plate 18, to improve the luminous uniformity coefficient of LCD 50.The overlapping order of each member of LCD shown in Figure 5 can be changed mutually, for example diffusion sheet 24 can with the location swap of protective sheet 21, prismatic lens 22 tops also can add another prismatic lens (not shown), wherein the prism arrangement direction of digonous eyeglass is orthogonal, also can omit prismatic lens 22, and the light exit surface of light guide plate 18 is designed to prism facets.

Fig. 6 is the liquid crystal indicator decomposing schematic representation with LCD shown in Figure 5 50, and wherein LCD 50 is combined in a back housing 500 and a front housing 520.One side of back housing 500 has the side screw 211 that a plurality of screws 510 are aligned in second framework 210, by fixture for example bolt 512 pass screw 510,211, LCD 50 and back housing 500 are combined.Front housing 520 engages with back housing 500 by the engaging mode again, so that LCD 50 is contained between the two.

Situation after the side light type backlight modular unit 30 that comprises different a plurality of diffusing structure 16 arrangement modes in the utility model and display panels 40 combinations is shown in Fig. 7 A-J, one LCD 50 comprises one or a plurality of light reflecting cover 12, one or a plurality of light source 14, a plurality of diffusing structures 16, one light guide plate 18, one reflecting piece 20, one protective sheet 21, one prismatic lens 22, one diffusion sheet 24 and a liquid crystal panel 28, after light is incident in the light guide plate 18 by light source 14, part light is projected to the surface that is scattered to light guide plate 18 behind the diffusing structure 16 through total reflection repeatedly and penetrates, another part light reflexes to the surface ejaculation of light guide plate 18 through the reflecting piece 20 of below, light guide plate 18 bottom surfaces, the light that penetrated by light guide plate 18 surface will more even after via diffusion sheet 24, and light can make after via prismatic lens 22 and has even and appropriate brightness in the angular field of view of LCD 50.

In Fig. 7 A, light guide plate 18 comprise with a same intervals from light source 14 sides toward light source 14 reverse directions from shallow to deep ground swell arise from the parallel conductive tabula rasa in the tool bilateral marginal ray source 14 of the diffusing structure 16 in light guide plate 18 bottom surfaces; In Fig. 7 B, light guide plate 18 comprise with a same intervals from light source 14 sides toward light source the 14 reverse direction depths swell the parallel conductive tabula rasa in tool bilateral marginal ray source 14 of the diffusing structure 16 in light guide plate 18 bottom surfaces erratically; In Fig. 7 C, light guide plate 18 comprise with a same intervals from light source 14 sides toward light source 14 reverse directions from shallow to deep ground swell arise from the double-wedge light guide plate in the tool bilateral marginal ray source 14 of the diffusing structure 16 in light guide plate 18 bottom surfaces; In Fig. 7 D, light guide plate 18 comprise with a same intervals from light source 14 sides toward light source the 14 reverse direction depths swell the double-wedge light guide plate in tool bilateral marginal ray source 14 of the diffusing structure 16 in light guide plate 18 bottom surfaces erratically; In Fig. 7 E, light guide plate 18 comprises the parallel conductive tabula rasa that protrudes in the tool bilateral marginal ray source 14 of the diffusing structure 16 outside light guide plate 18 bottom surfaces with a same intervals from light source 14 sides toward light source 14 reverse directions from shallow to deep; In Fig. 7 F, light guide plate 18 comprises the parallel conductive tabula rasa that protrudes in the tool bilateral marginal ray source 14 of the diffusing structure 16 outside light guide plate 18 bottom surfaces with a same intervals from light source 14 sides toward the light source 14 reverse direction depths erratically; In Fig. 7 G, light guide plate 18 comprises the double-wedge light guide plate that protrudes in the tool bilateral marginal ray source 14 of the diffusing structure 16 outside light guide plate 18 bottom surfaces with a same intervals from light source 14 sides toward light source 14 reverse directions from shallow to deep; In Fig. 7 H, light guide plate 18 comprises the double-wedge light guide plate that protrudes in the tool bilateral marginal ray source 14 of the diffusing structure 16 outside light guide plate 18 bottom surfaces with a same intervals from light source 14 sides toward the light source 14 reverse direction depths erratically; In Fig. 7 I, light guide plate 18 comprises with a same intervals from the parallel conductive tabula rasa of past light source 14 reverse directions of light source 14 sides by the tool bilateral marginal ray source 14 that is deep to the diffusing structure 16 that protrudes in outside light guide plate 18 bottom surfaces shallowly; In Fig. 7 J, light guide plate 18 comprises with a same intervals from the double-wedge light guide plate of past light source 14 reverse directions of light source 14 sides by the tool bilateral marginal ray source 14 that is deep to the diffusing structure 16 that protrudes in outside light guide plate 18 bottom surfaces shallowly.

The above is preferred embodiment of the present utility model only, is not in order to limit claim of the present utility model.Still can be changed in the category that does not break away from flesh and blood of the present utility model and implemented, these variations should still belong to scope of the present utility model.Therefore, category of the present utility model is defined by described claim.

Claims (9)

1. a backlight modular unit light guide plate scattering arrangement architecture is characterized in that, comprises:

One light guide plate, this light guide plate comprise a surface and a bottom surface;

At least one light source, this at least one light source are installed at least one side of this light guide plate to launch light in this light guide plate;

At least one light reflecting cover, this at least one light reflecting cover surrounds this at least one light source in order to reflection ray; And

A plurality of scattering arrangement architectures, these a plurality of scattering arrangement architectures be positioned at this light guide plate the bottom surface near, and the different depths of these a plurality of scattering arrangement architecture tools, these a plurality of scattering arrangement architectures make light reflex to this surface of this light guide plate in order to the total reflection that destroys light.

2. backlight modular unit light guide plate scattering arrangement architecture as claimed in claim 1, it is characterized in that, above-mentioned a plurality of scattering arrangement architectures are positioned at this light guide plate, and these a plurality of scattering arrangement architectures are arranged toward the reverse direction of this at least one light source with fixed intervals and mode from shallow to deep by this light guide plate side that this at least one light source is installed.

3. backlight modular unit light guide plate scattering arrangement architecture as claimed in claim 1, it is characterized in that, above-mentioned a plurality of scattering arrangement architectures are positioned at this light guide plate, and these a plurality of scattering arrangement architectures by this light guide plate side that this at least one light source is installed with fixed intervals but the indefinite mode of the depth toward the reverse direction arrangement of this at least one light source.

4. backlight modular unit light guide plate scattering arrangement architecture as claimed in claim 1, it is characterized in that, above-mentioned a plurality of scattering arrangement architectures be positioned at this light guide plate outside, and these a plurality of scattering arrangement architectures by this light guide plate side that this at least one light source is installed with the reverse direction arrangement of fixed intervals and mode from shallow to deep toward this at least one light source.

5. backlight modular unit light guide plate scattering arrangement architecture as claimed in claim 1, it is characterized in that, above-mentioned a plurality of scattering arrangement architectures be positioned at this light guide plate outside, and these a plurality of scattering arrangement architectures by this light guide plate side that this at least one light source is installed with fixed intervals and by being deep to shallow mode toward the arrangement of the reverse direction of this at least one light source.

6. backlight modular unit light guide plate scattering arrangement architecture as claimed in claim 1, it is characterized in that, above-mentioned a plurality of scattering arrangement architectures be positioned at this light guide plate outside, and these a plurality of scattering arrangement architectures by this light guide plate side that this at least one light source is installed with of the reverse direction arrangement of the indefinite mode of fixed intervals and the depth toward this at least one light source.

7. backlight modular unit light guide plate scattering arrangement architecture as claimed in claim 1 is characterized in that above-mentioned light guide plate comprises a parallel-plate.

8. backlight modular unit light guide plate scattering arrangement architecture as claimed in claim 1 is characterized in that above-mentioned light guide plate comprises a clapboard.

9. backlight modular unit light guide plate scattering arrangement architecture as claimed in claim 1 is characterized in that, above-mentioned light guide plate comprises the thick and central thin folding wedge template in both sides.

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