CN1952756A - LCD panel module - Google Patents

Abstract

The invention provides a liquid crystal display panel module, the liquid crystal display panel module includes a first baseboard; a second baseboard; a liquid crystal layer that lies between the fist baseboard and the second baseboard; a first polarized board, which lies on the surface of the first baseboard, has a first inflated ratealpha1; a second polarized board, which lies on the surface of the second baseboard, has a second inflated rate alpha2; a first gluey-layer, which forms between the first polarized board and the first baseboard, has a first thickness h1; and a second gluey-layer, which forms between the second polarized board and the second baseboard, has a second thickness h2; wherein the first thickness h1 is different from the second thickness h2, and the first inflated ratealpha1 is the same as the second inflated rate alpha2. The liquid crystal display panel module of the invention will not warp due to the perennial roast from the backlight module, so as to cause the phenomena of 'fringe leaking-light', and further will not scathe the backlight.

Description

LCD panel module

Technical field

The present invention is about a kind of LCD panel module, refer to especially a kind of can be because of being subjected to the baking buckling deformation of backlight module for a long time so that the LCD panel module (PanelModule) of " edge light leak " phenomenon takes place.

Background technology

In a LCD panel module, its Polarizer has the function of modulation by the polarization direction (polarization) of the light of itself, controls the switch of the display unit (pixel) of a display panels with the collocation liquid crystal molecule.Figure 1A is the synoptic diagram of existing application in the Polarizer 1 of a LCD panel module; it comprises that a Polarizer body 11 and two that is made of polyvinyl alcohol (PVA) (PVA) lays respectively at its protective seam 121 of both sides up and down; 122, and this Polarizer 1 is attached to the surface of glass substrate 14 again by pressure-sensitive solid (PSA) 13.

When a LCD panel module with the Polarizer shown in Figure 1A after using for a long time; display panels is toasted for a long time by backlight module and heats; its " contraction internal stress " of Polarizer shown in Figure 1A can be because its Polarizer body 11 and protective seam 121; 122 have that the thermal expansivity of different numerical value and pressure-sensitive solid (PSA) 13 stickiness reduce gradually because of being heated former thereby change, and the amplitude that its " contraction internal stress " changes can increase along with the increase of temperature.

The available liquid crystal display module is after long-time the use, Polarizer is because of close backlight module under it, therefore the temperature of the last Polarizer of Polarizer temperature is high down, causes down " the contraction internal stress " of Polarizer unequal with " the contraction internal stress " of last Polarizer.Because the contraction internal stress reason of unbalanced of Polarizer up and down, make the phenomenon of available liquid crystal display panel generation buckling deformation, shown in Figure 1B.Because the phenomenon of this buckling deformation, " edge light leak " phenomenon just can take place in the edge of available liquid crystal display module, and its display panels middle body easily comes in contact with the backlight module 16 that is positioned at its below, and causes the defective of the blooming (as diffusion barrier) of backlight module.So available liquid crystal display module 15 is after using for a long time, its display quality just can be affected because of the defective of the blooming of " edge light leak " phenomenon and backlight module.

Therefore, industry needs a kind of display panels, can be because of not being subjected to the baking buckling deformation of backlight module for a long time, thus " edge light leak " phenomenon, the display quality that has the LCD monitor or the LCD TV of this LCD panel module with improvement take place in LCD panel module.

Summary of the invention

A kind of LCD panel module comprises: one first substrate; One second substrate; One liquid crystal layer is between first substrate and second substrate; One first Polarizer be positioned at the surface of first substrate, and first Polarizer has one first coefficient of thermal expansion α ₁One second Polarizer be positioned at the surface of second substrate, and second Polarizer has one second coefficient of thermal expansion α ₂One is formed at first glue-line between first Polarizer and first substrate, and it has one first thickness h ₁And second glue-line that is formed between second Polarizer and second substrate, it has one second thickness h ₂, wherein, the first coefficient of thermal expansion α ₁With the second coefficient of thermal expansion α ₂Identical.

A kind of LCD panel module comprises: one first substrate; One second substrate; One liquid crystal layer is between first substrate and second substrate; One first Polarizer be positioned at the surface of first substrate, and first Polarizer has one first coefficient of thermal expansion α ₁One second Polarizer be positioned at the surface of second substrate, and second Polarizer has one second coefficient of thermal expansion α ₂One is formed at first glue-line between first Polarizer and first substrate, and it has one first thickness h ₁And second glue-line that is formed between second Polarizer and second substrate, it has one second thickness h ₂, wherein, first thickness h ₁With second thickness h ₂Identical, and the first coefficient of thermal expansion α ₁With the second coefficient of thermal expansion α ₂Different.

Therefore, if use following dual mode one of them: when (1) has identical material when first Polarizer that is applied to a LCD panel module with second Polarizer, make comparatively thickness (h near " second glue-line " of backlight module ₂) thickness (h of " first glue-line " ₁) be thick mode; (2) as the thickness (h of first glue-line that is applied to a LCD panel module ₁) with the thickness (h of second glue-line ₂) when equating, make the thermal expansivity (α of the Polarizer of winning _P1) greater than the thermal expansivity (α of second Polarizer _P2) mode; The phenomenon of buckling deformation just can not take place because of the baking that is subjected to being positioned at the backlight module under it for a long time in display panels then of the present invention.So even if LCD panel module of the present invention is through after using for a long time, phenomenon of " edge light leak " (or dark attitude light leak) still can not take place for it, and can reduce it and contact the defective that is caused with the blooming of backlight module because of buckling deformation.

LCD panel module of the present invention can have first Polarizer of any material, and its material is preferably polyvinyl alcohol (PVA).LCD panel module of the present invention can have second Polarizer of any material, and its material is preferably polyvinyl alcohol (PVA).First Polarizer of LCD panel module of the present invention can more comprise first protective seam of any material in its surface, and its material is preferably the compound substance or the cyclic olefin of acetic acid three cellophanes (TAC), acetic acid three cellophanes and disc-like liquid crystal (DLC).Second Polarizer of LCD panel module of the present invention can more comprise second protective seam of any material in its surface, and its material is preferably the compound substance or the cyclic olefin of acetic acid three cellophanes (TAC), acetic acid three cellophanes and disc-like liquid crystal (DLC).LCD panel module of the present invention can have first glue-line of any material, and its material is preferably pressure-sensitive solid or hot-setting adhesive.LCD panel module of the present invention can have second glue-line of any material, and its material is preferably pressure-sensitive solid or hot-setting adhesive.First glue-line of LCD panel module of the present invention can have any thickness, between 0.1 times to 0.7 times of the preferable thickness between second glue-line of scope (second thickness) of its thickness (first thickness).LCD panel module of the present invention can be applicable in the display device of any kind of, and its preferred application is in a LCD monitor or a LCD TV.First Polarizer of LCD panel module of the present invention can have the coefficient of thermal expansion of any scope, between 1.0 times to 5.5 times of the preferable coefficient of thermal expansion between second Polarizer of scope (second coefficient of thermal expansion) of its coefficient of thermal expansion (first coefficient of thermal expansion).

Description of drawings

Figure 1A represents the existing synoptic diagram that is applied to the Polarizer of a LCD panel module.

Figure 1B represents the available liquid crystal display module after long-time the use, whole liquid crystal display panel module Yin Gaore and the synoptic diagram that bending phenomenon occurs.

Fig. 2 A represents that one is applied to the synoptic diagram of simplified model of the Polarizer of the derivation of equation.

Fig. 2 B represents that one is applied to the synoptic diagram of simplified model of the Polarizer of the derivation of equation.

Fig. 3 A represents that one is applied to the synoptic diagram of simplified model of the Polarizer of the derivation of equation, and wherein this LCD panel module is not heated by backlight module as yet.

Fig. 3 B represents that one is applied to the synoptic diagram of simplified model of the Polarizer of the derivation of equation, and wherein this LCD panel module is because heated by backlight module and deform.

Fig. 4 represents that one is applied to the synoptic diagram of the LCD panel module of the derivation of equation.

Fig. 5 represents the synoptic diagram of the LCD panel module of the present invention's first preferred embodiment.

Fig. 6 represents the synoptic diagram of the LCD panel module of the present invention's second preferred embodiment.

The primary clustering symbol description

11 Polarizer bodies

121,122 protective seams

13 pressure-sensitive solids

14 glass substrates

15 LCD panel modules

16 backlight modules

21 glass substrates

22 glue-lines

23 Polarizer bodies

31 glass substrates

32 glue-lines

33 Polarizer bodies

41 first Polarizers

42 first glue-lines

43 first substrates

44 second substrates

45 second glue-lines

46 second Polarizers

47 backlight modules

51 first Polarizers

52 first glue-lines

53 first substrates

54 second substrates

55 second glue-lines

56 second Polarizers

57 backlight modules

61 first Polarizers

62 first glue-lines

63 first substrates

64 second substrates

65 second glue-lines

66 second Polarizers

67 backlight modules

Embodiment

See also Fig. 2 A and Fig. 2 B, both represent to be applied to the synoptic diagram of simplified model of the Polarizer of derivation of equation process.Shown in Fig. 2 A and Fig. 2 B, Polarizer comprises glass substrate (H) 21, a glue-line (G) 22 and Polarizer body (P) 23, and wherein Polarizer body 23 is attached to the surface of glass substrate 21 by glue-line 22.

In addition, be present in derivation LCD panel module of the present invention two Polarizers up and down " thermal expansivity " and two Polarizers are attached to respectively before the relational expression between two glue-lines " thickness " of upper and lower base plate of LCD panel module of the present invention, following hypothesis must be established earlier, with the process of formula of reduction derivation, and these hypothesis are as described below:

1. LCD panel module of the present invention has a laterally zygomorphic structure.

2. Polarizer of LCD panel module of the present invention (P) and glass substrate (H) can shrink to its central authorities because of the cause of being heated, and the shrinkage degree of glass substrate (H) is much smaller than the shrinkage degree of glue-line (G).

3. when the Polarizer (P) of LCD panel module of the present invention shrank, it can apply a shear V (shear force) in glue-line (G).

4. the contraction of glass substrate (H) can make glue-line (G) be subjected to displacement, but glass substrate (H) can't move along with the displacement of glue-line (G).

5. glue-line (G) is an incompressible fluid, and the pressure at right angle (normalstress) that puts on glue-line (G) is negligible.

6. glue-line (G) only limits to be parallel to the directions X shown in Fig. 2 B and moves, and the mobile speed of glue-line (G) can't change along with the time.

7. the pressure on directions X is changed to continuously and changes.

8. the temperature of whole liquid crystal display panel module only changes on the Y direction shown in Fig. 2 B, and it is changed to linear change.

Then, based on above-mentioned hypothesis, can write out the continuity formula (equation of continuity) that is present in this Polarizer simplified model, i.e. mass balance (mass balance)

(0 in the formula (1) is in the bottom of each arrow, and the expression item that arrow streaked is tending towards 0); And

Be parallel to the momentum formula (equation ofmomentum in X-direction) on the directions X, i.e. energy balance (energy balance)

(0 in the formula (2) is in the bottom of each arrow, and the expression item that arrow streaked is tending towards 0) and power theorem (Power law):

${\mathrm{\τ}}_{\mathrm{yx}}=-m\stackrel{\·}{{\mathrm{\γ}}^n}=-m{\left(\frac{{\mathrm{dv}}_x}{\mathrm{dy}}\right)}^n=\frac{V}{\mathrm{LM}}(\stackrel{\·}{\mathrm{\γ}}:\mathrm{strain\; rate})$

$\⇒\frac{{\mathrm{dv}}_x}{\mathrm{dy}}=-{\left(\frac{V}{\mathrm{mLW}}\right)}^{1/n}$

$\⇒v_x=-{\left(\frac{V}{\mathrm{mLW}}\right)}^{1/n}y+C_1$ Formula (3)

Wherein, C ₁It is a constant.

At this moment, introduce boundary condition (Boundary Condition) y=0 and Vx=0 again after, formula (3) can be streamlined any further and is following formula:

$\⇒v_x=-{\left(\frac{V}{\mathrm{mLW}}\right)}^{1/n}y$ Formula (4)

Then, see also Fig. 3 A and Fig. 3 B, wherein Fig. 3 A shows that one is applied to the synoptic diagram of simplified model of the Polarizer of the derivation of equation, and in this figure, this LCD panel module is not positioned at the backlight module heating of its below as yet.On the other hand, Fig. 3 B shows that one is applied to the synoptic diagram of simplified model of the LCD panel module of the derivation of equation, and in this figure, this LCD panel module deforms because of the backlight module that is positioned at its below heats.Polarizer comprises glass substrate (H) 31, glue-line (G) 32 and Polarizer body (P) 33, and wherein Polarizer body 33 is attached to the surface of glass substrate 31 by glue-line 32.

Shown in Fig. 3 B, the contraction that glass substrate 31 produces because be heated makes glue-line 32 produce G (δ _TH) displacement, and the big I of this displacement is expressed as follows:

δ _TH=ε _THL=α _H(Δ T _P) L formula (5)

Wherein, ε _THBe the thermal strain (heat strain) of glass substrate 31, α _HIt then is the thermal expansivity (heat expansion coefficient) of glass substrate 31.

In addition, the contraction of Polarizer body 33 can apply a shear V in glue-line 32, and makes glue-line 32 produce a shearing strain (shear strain), and

d＝δ _TP-δ _TH，

Wherein, δ _TPCan further be expressed as:

δ _TP=ε _TPL=α _P(Δ T _P) L formula (6)

And in formula (6), ε _TPBe the thermal strain (heat strain) of Polarizer body 33, α _HThen be the thermal expansivity (heat expansion coefficient) of Polarizer body 33, and d also can be expressed as following formula:

$d=h\tan \mathrm{\γ}\≈\mathrm{h\γ}=\frac{\mathrm{hV}}{(L-{\mathrm{\δ}}_{\mathrm{TP}})W{G}_g}=\frac{\mathrm{hV}}{(1-{\mathrm{\α}}_P\left(\mathrm{\Δ}{T}_P\right))\mathrm{LW}{G}_g}$ Formula (7)

In formula (7), h is glue-line 32 (pressure-sensitive solid, thickness PSA), G _gBe the shearing modulus (shear modulus) of pressure-sensitive solid, γ is the shearing strain (shear strain) of pressure-sensitive solid.

And, can obtain following formula through after the suitable computing:

$\⇒{\mathrm{\α}}_P\left(\mathrm{\Δ}{T}_P\right)\·L-{\mathrm{\α}}_H\left(\mathrm{\Δ}{T}_H\right)\·L=\frac{\mathrm{hV}}{(1-{\mathrm{\α}}_P\left(\mathrm{\Δ}{T}_p\right))\mathrm{LW}{G}_g}$

$\⇒V=\frac{[{\mathrm{\α}}_P\left(\mathrm{\Δ}{T}_P\right)-{\mathrm{\α}}_H\left(\mathrm{\Δ}{T}_H\right)](1-{\mathrm{\α}}_P\left(\mathrm{\Δ}{T}_P\right))L^{2}W{G}_g}{h}$ Formula (8)

At last, with formula (8) substitution formula (4), can obtain

$v_{\mathrm{xi}}=-{[\frac{[{\mathrm{\α}}_P\left(\mathrm{\Δ}{T}_P\right)-{\mathrm{\α}}_H\left(\mathrm{\Δ}{T}_H\right)](1-{\mathrm{\α}}_P\left(\mathrm{\Δ}{T}_P\right))L^{2}W{G}_g}{h_i}\·\frac{1}{\mathrm{mLW}}]}^{1/n_i}y$

$=-{\left[\frac{[{\mathrm{\α}}_P\left(\mathrm{\Δ}{T}_P\right)-{\mathrm{\α}}_H\left(\mathrm{\Δ}{T}_H\right)](1-{\mathrm{\α}}_P\left(\mathrm{\Δ}{T}_P\right)){\mathrm{LG}}_g}{{\mathrm{mh}}_i}\right]}^{1/n_i}y$ Formula (9)

At this moment, first Polarizer for being positioned at the LCD panel module first half is set at i=1; And, be set at i=2 to being positioned at second Polarizer of LCD panel module Lower Half.In addition, work as y=h ₁And y=h ₂The time, V _X1Equal V _X2

$\frac{v_{x1}}{v_{x2}}=\frac{h_1}{h_2}{\left[\frac{[{\mathrm{\α}}_{p1}\left(\mathrm{\Δ}{T}_{p1}\right)-{\mathrm{\α}}_{H1}\left(\mathrm{\Δ}{T}_{H1}\right)](1-{\mathrm{\α}}_{P1}\left(\mathrm{\Δ}{T}_{T1}\right))G_{g1}}{m_1{h}_1}\right]}^{1/n_1}{\left[\frac{m_2{h}_2}{[{\mathrm{\α}}_{P2}\left(\mathrm{\Δ}{T}_{P2}\right)-{\mathrm{\α}}_{H2}\left(\mathrm{\Δ}{T}_{H2}\right)](1-{\mathrm{\α}}_{P2}\left(\mathrm{\Δ}{T}_{P2}\right)){\mathrm{Gg}}_2}\right]}^{1/n2}{L}^{(1/n_1-1/n_2)}$

$={\left[\frac{{\mathrm{\&alpha;}}_{P1}\left(\mathrm{\&Delta;}{T}_{P1}\right)-{\mathrm{\&alpha;}}_{H1}\left(\mathrm{\&Delta;}{T}_{H1}\right)](1-{\mathrm{\&alpha;}}_{P1}\left(\mathrm{\&Delta;}{T}_{P1}\right))G_{g1}}{m_1}\right]}^{1/n_1}[{\frac{{\mathrm{<figure-callout\; id="2"\; label="m"\; filenames="A20061014862300231.png"\; state="\{\{state\}\}">m</figure-callout>}}_2}{{\mathrm{\&alpha;}}_{P2}\left(\mathrm{\&Delta;}{T}_{P2}\right)-{\mathrm{\&alpha;}}_{H2}(\mathrm{\&Delta;}{T}_{H2})](1-{\mathrm{\&alpha;}}_{P2}\left(\mathrm{\&Delta;}{T}_{P2}\right))G_{g2}}]}^{1/n2}{L^{(1/n_1-1/n_2)}}^{}\frac{h_1^{(1-1/n_1)}}{h_2^{(1-1/n_2)}}$

＝1

Formula (10)

And the glass substrate (H) that all uses identical material when first Polarizer (being the situation of i=1) and second Polarizer (being the situation of i=2) is during with identical pressure-sensitive solid (PSA), α _H1=α _H2=α _Hm ₁=m ₂=m; n ₁=n ₂=n; G _G1=G _G2=G _g, and quite complicated originally formula (10) can significantly be reduced to following formula:

$\left[\frac{[{\mathrm{\&alpha;}}_{P1}\left(\mathrm{\&Delta;}{T}_{P1}\right)-{\mathrm{\&alpha;}}_H\left(\mathrm{\&Delta;}{T}_{H1}\right)](1-{\mathrm{\&alpha;}}_{P1}\left(\mathrm{\&Delta;}{T}_{P1}\right))}{\left[{\mathrm{\&alpha;}}_{P2}\left(\mathrm{\&Delta;}{T}_{P2}\right)-{\mathrm{\&alpha;}}_H\left(\mathrm{\&Delta;}{T}_{H2}\right)\right](1-{\mathrm{\&alpha;}}_{P2}\left(\mathrm{\&Delta;}{T}_{P2}\right))}\right]={\left(\frac{h_1}{h_2}\right)}^{1-n}$ Formula (11)

After a while, to utilize formula (11) to derive and be present in the employed Polarizer material of LCD panel module of the present invention (as thermal expansivity) and " thickness " the preferable relational expression between the two of fixing the glue-line of the required use of these Polarizers, make LCD panel module of the present invention can not cause the generation of " edge light leak " phenomenon because of being subjected to the baking buckling deformation of backlight module for a long time.

Below, will be with the example that is applied as of LCD monitor (monitor):

When normal the use, the temperature of the first half of the LCD panel module that a LCD monitor is had is about 30 ℃, and the temperature of its Lower Half (than the part near backlight module) then is about 35 ℃.And as previously mentioned, the Temperature Distribution of this LCD panel module is linear distribution, and the temperature of its inner arbitrary position can be expressed as:

T=T ₀+ ky formula (12)

Wherein, T is the temperature of the inner arbitrary position of LCD panel module of the present invention, and k then is heat-conduction coefficient (thermal conductivity).

As shown in Figure 4, LCD panel module of the present invention comprises the first Polarizer (P ₁) 41, the first glue-line (G ₁) 42, the first substrate (H ₁) 43, the second substrate (H ₂) 44, the second glue-line (G ₂) the 45 and second Polarizer (P ₂) 46, its integral thickness is about 1.68mm.In addition, LCD panel module of the present invention is positioned on the backlight module 47 (B/L), to accept light source that backlight module 47 provided to show customizing messages or image.

So in LCD panel module shown in Figure 4, heat-conduction coefficient k is 2.98 ℃/mm, and the temperature of its each interface is as shown in table 1 below:

A layer material/b layer material	The thickness of a layer material (mm)	The thermograde of a layer material (℃)	Be present in the interface between a layer material and the b layer material temperature value (℃)
				air/P 1	0	0	30
P 1/H 1	0.215	0.64	30.64
				G 1/H 1	0.025	0.07	30.71
H 1/H 2	0.6	1.79	32.50
				H 2/G 2	0.6	1.79	34.29
G 2/P 2	0.025	0.07	34.36
				P 2/BL	0.215	0.64	35.00
Amount to	1.68	5.00

Table 1

Wherein, the temperature of each layer is all represented with the medial temperature (average temperature) of this layer.On the other hand, the thermal expansivity of first substrate 43 of glass material and second substrate 44 is 3.2 * 10 ^-6℃ ^-1, the thermal expansivity of first Polarizer 41 and second Polarizer 46 then is 3.0 * 10 ^-5℃ ^-1So, if, then can obtain following table 2 with in the aforesaid thermal expansivity difference substitution table 1:

	Medial temperature (℃)	ΔT	αΔT	1/αΔT	α HΔT/α PΔT	1-(α HΔT/α PΔT)
							T P1	30.32	5.32	1.60E-04	6.27E+03	1.32E-01	8.68E-01
T H1	31.605	6.605	2.11E-05	4.73E+04
					T H2	33.395	8.395	2.69E-05	3.72E+04	9.25E-02	9.07E-01
T P2	34.68	9.68	2.90E-04	3.44E+03

Table 2

From table 2, can find out, no matter be the first half or the Lower Half (being the situation of i=1 and i=2) of liquid crystal panel module, its α _HΔ T/ α _PΔ T all is about 0.10, feasible (1-α _HΔ T/ α _PΔ T) all approaches 1 in two kinds of situations (being the situation of i=1 and i=2).Therefore, the left side of aforesaid formula (11) can further again abbreviation be:

$\left[\frac{[{\mathrm{\&alpha;}}_{P1}\left({\mathrm{\&Delta;T}}_{P1}\right)-{\mathrm{\&alpha;}}_H\left({\mathrm{\&Delta;T}}_{H1}\right)](1-{\mathrm{\&alpha;}}_{P1}\left({\mathrm{\&Delta;T}}_{P1}\right))}{[{\mathrm{\&alpha;}}_{P2}\left({\mathrm{\&Delta;T}}_{P2}\right)-{\mathrm{\&alpha;}}_H\left({\mathrm{\&Delta;T}}_{H2}\right)](1-{\mathrm{\&alpha;}}_{P2}\left({\mathrm{\&Delta;T}}_{P2}\right))}\right]$

$=\frac{{{\mathrm{\&alpha;}}_{P1}}^2{\left({\mathrm{\&Delta;T}}_{P1}\right)}^2[1-{\mathrm{\&alpha;}}_H\left({\mathrm{\&Delta;T}}_{H1}\right)/{\mathrm{\&alpha;}}_{P1}\left({\mathrm{\&Delta;T}}_{P1}\right)][1/{\mathrm{\&alpha;}}_{P1}{\left({\mathrm{\&Delta;T}}_{P1}\right)}^{-1}]}{{{\mathrm{\&alpha;}}_{\mathrm{<figure-callout\; id="2"\; label="P"\; filenames="A20061014862300231.png"\; state="\{\{state\}\}">P</figure-callout>}2}}^2{\left({\mathrm{\&Delta;T}}_{P2}\right)}^2[1-{\mathrm{\&alpha;}}_H\left({\mathrm{\&Delta;T}}_{H2}\right)/{\mathrm{\&alpha;}}_{P2}\left(\mathrm{\&Delta;}{T}_{P2}\right)][1/{\mathrm{\&alpha;}}_{P2}{\left({\mathrm{\&Delta;T}}_{P2}\right)}^{-1}]}$

$\&ap;\frac{{{\mathrm{\&alpha;}}_{P1}}^2{\left({\mathrm{\&Delta;T}}_{P1}\right)}^2\&times;1\&times;1/{\mathrm{\&alpha;}}_{P1}\left({\mathrm{\&Delta;T}}_{P1}\right)}{{{{\mathrm{\&alpha;}}_{\mathrm{<figure-callout\; id="2"\; label="P"\; filenames="A20061014862300231.png"\; state="\{\{state\}\}">P</figure-callout>}2}}^2\left({\mathrm{\&Delta;T}}_{P2}\right)}^2\&times;1\&times;1/{\mathrm{\&alpha;}}_{P2}\left({\mathrm{\&Delta;T}}_{P2}\right)}$

$=\frac{{\mathrm{\&alpha;}}_{P1}\left({\mathrm{\&Delta;T}}_{P1}\right)}{{\mathrm{\&alpha;}}_{P2}\left(\mathrm{\&Delta;}{T}_{P2}\right)}$

Therefore, under situation shown in Figure 4, aforesaid formula (11) can be reduced to:

$\frac{{\mathrm{\&alpha;}}_{P1}\left(\mathrm{\&Delta;}{T}_{P1}\right)}{{\mathrm{\&alpha;}}_{P2}\left(\mathrm{\&Delta;}{T}_{P2}\right)}={\left(\frac{h_1}{h_2}\right)}^{1-n}$ Formula (13)

Below, will with two preferred embodiments explanation be present in LCD panel module of the present invention two Polarizers up and down " thermal expansivity " and this two Polarizer is attached to relation between " thickness " of two glue-lines of upper and lower base plate of LCD panel module of the present invention respectively.

The structure of the LCD panel module of the present invention's first preferred embodiment as shown in Figure 5, it comprises the first Polarizer (P ₁) 51, the first glue-line (G ₁) 52, the first substrate (H ₁) 53, the second substrate (H ₂) 54, the second glue-line (G ₂) the 55 and second Polarizer (P ₂) 56.In addition, the LCD panel module of the present invention's first preferred embodiment is positioned on the backlight module (B/L) 57, to accept light source that backlight module 57 provided to show customizing messages or image.

In addition, because the LCD panel module of the present invention's first preferred embodiment uses first Polarizer 51 and second Polarizer 56, the i.e. α of identical material _P1Equal α _P2So aforesaid formula (13) can be reduced to:

$\frac{h_1}{{\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20061014862300231.png"\; state="\{\{state\}\}">h</figure-callout>}}_2}={\left(\frac{{\mathrm{\&Delta;<figure-callout\; id="2"\; label="T\; P"\; filenames="A20061014862300231.png"\; state="\{\{state\}\}">T</figure-callout>}}_P}{{\mathrm{\&Delta;T}}_{P1}}\right)}^{1/1-n}$ Formula (14)

On the other hand, because first glue-line 52 and second glue-line 55 of the LCD panel module of the present invention's first preferred embodiment are pressure-sensitive solid (PSA), promptly n is that the exponential quantity of power theorem is about 0.54, and Δ T _P1=5 ℃; Δ T _P2=10 ℃ (situation as shown in Figure 4), aforesaid formula (14) but computing is as follows:

$\frac{h_1}{{\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20061014862300231.png"\; state="\{\{state\}\}">h</figure-callout>}}_2}={\left(\frac{{\mathrm{\&Delta;<figure-callout\; id="2"\; label="T\; P"\; filenames="A20061014862300231.png"\; state="\{\{state\}\}">T</figure-callout>}}_P}{{\mathrm{\&Delta;T}}_{P1}}\right)}^{1/n-1}={\left(\frac{10}{5}\right)}^{1/0.54-1}=0.22$

Hence one can see that, in the LCD panel module of the present invention's first preferred embodiment, as the thickness (h of first glue-line 52 ₁) near second glue-line, 55 (h ₂) 0.22 times the time, even if the LCD panel module of the present invention's first preferred embodiment toasts heating for a long time through the backlight module that is positioned under it, the phenomenon of buckling deformation still can not take place in its edge, and the phenomenon of " edge light leak " can not take place feasible LCD monitor with LCD panel module of the present invention's first preferred embodiment.Promptly, when the thickness of first glue-line 52 is about 25 μ m, if the thickness of second glue-line 55 is about the words of 113.64 μ m, then have these two kinds of different-thickness glue-line (pressure-sensitive solid) even if the LCD panel module of the present invention's first preferred embodiment toast heating for a long time through the backlight module that is positioned under it, the phenomenon of buckling deformation still can not take place in its edge.

Fig. 6 is the synoptic diagram of the LCD panel module of the present invention's second preferred embodiment, and its LCD panel module that shows the present invention's second preferred embodiment comprises the first Polarizer (P ₁) 61, the first glue-line (G ₁) 62, the first substrate (H ₁) 63, the second substrate (H ₂) 64, the second glue-line (G ₂) the 65 and second Polarizer (P ₂) 66.In addition, the LCD panel module of the present invention's first preferred embodiment is positioned on the backlight module (B/L) 67, to accept light source that backlight module 67 provided to show customizing messages or image.

In addition, because the LCD panel module of the present invention's second preferred embodiment uses first glue-line 62 and second glue-line 65 of same thickness, promptly h1 equals h2, so aforesaid formula (13) can be reduced to:

$\frac{{\mathrm{\&alpha;}}_{P1}}{{\mathrm{\&alpha;}}_{\mathrm{<figure-callout\; id="2"\; label="P"\; filenames="A20061014862300231.png"\; state="\{\{state\}\}">P</figure-callout>}2}}=\frac{\mathrm{\&Delta;}{\mathrm{<figure-callout\; id="2"\; label="T\; P"\; filenames="A20061014862300231.png"\; state="\{\{state\}\}">T</figure-callout>}}_P}{\mathrm{\&Delta;}{T}_{P1}}$ Formula (15)

On the other hand, because Δ T _P1=5 ℃; Δ T _P2=10 ℃ (situation as shown in Figure 4), aforesaid formula (15) then can be rewritten as:

$\frac{{\mathrm{\&alpha;}}_{P1}}{{\mathrm{\&alpha;}}_{\mathrm{<figure-callout\; id="2"\; label="P"\; filenames="A20061014862300231.png"\; state="\{\{state\}\}">P</figure-callout>}2}}=\frac{{\mathrm{\&Delta;<figure-callout\; id="2"\; label="T\; P"\; filenames="A20061014862300231.png"\; state="\{\{state\}\}">T</figure-callout>}}_P}{\mathrm{\&Delta;}{T}_{P1}}=\frac{10}{5}=2$

Hence one can see that, in the LCD panel module of the present invention's second preferred embodiment, as the thermal expansivity (α of first Polarizer 61 _P1) be the thermal expansivity (α of second Polarizer 66 _P2) 2 times the time, even if the LCD panel module of the present invention's second preferred embodiment toasts heating for a long time through the backlight module that is positioned under it, the phenomenon of buckling deformation still can not take place in its edge, and the phenomenon of " edge light leak " can not take place feasible LCD monitor with LCD panel module of the present invention's first preferred embodiment.That is, when the material of first Polarizer, 61 bodies is a polyvinyl alcohol (PVA), and the material of its protective seam (not shown) (its overall thermal expansion coefficient is about 4.4 * 10 when being acetic acid three cellophanes ^-5℃ ^-1), (Discotic Liquid Crystal, DLC) material combines that (its thermal expansivity is about 2.4 * 10 if the protective seam (not shown) of second Polarizer 66 is by acetic acid three cellophanes and disc-like liquid crystal ^-5℃ ^-1), then have these two kinds of Polarizers (first Polarizer 61 and second Polarizer 66) even if the LCD panel module of the present invention's second preferred embodiment toast heating for a long time through the backlight module that is positioned under it, the phenomenon of buckling deformation still can not take place in its edge.

In sum, by use following dual mode one of them: when (1) has identical material when first Polarizer that is applied to a LCD panel module with second Polarizer, make the thickness (h of " second glue-line " of comparatively close backlight module ₂) thickness (h of " first glue-line " ₁) be thick mode; (2) as the thickness (h of first glue-line that is applied to a LCD panel module ₁) with the thickness (h of second glue-line ₂) when equating, make the thermal expansivity (α of the Polarizer of winning _P1) greater than the thermal expansivity (α of second Polarizer _P2) mode; The phenomenon of buckling deformation just can not take place because of the baking that is subjected to being positioned at the backlight module under it for a long time in LCD panel module then of the present invention.So even if LCD panel module of the present invention is through after using for a long time, phenomenon of " edge light leak " (or dark attitude light leak) still can not take place for it, and can reduce it and contact the defective that is caused with the blooming of backlight module because of buckling deformation.

The foregoing description only is to give an example for convenience of description, and the interest field that the present invention advocated should be as the criterion so that claim is described, but not only limits to the foregoing description.

Claims (18)

1. LCD panel module, this LCD panel module comprises:

One first substrate;

One second substrate;

One liquid crystal layer is between described first substrate and described second substrate;

One first Polarizer be positioned at the surface of described first substrate, and described first Polarizer has one first coefficient of thermal expansion α ₁

One second Polarizer be positioned at the surface of described second substrate, and described second Polarizer has one second coefficient of thermal expansion α ₂

One is formed at first glue-line between described first Polarizer and described first substrate, and it has one first thickness h ₁And

One is formed at second glue-line between described second Polarizer and described second substrate, and it has one second thickness h ₂,

Wherein, described first thickness h ₁With described second thickness h ₂Difference, and the described first coefficient of thermal expansion α ₁With the described second coefficient of thermal expansion α ₂Identical.

2. LCD panel module as claimed in claim 1 is characterized in that, the material of described first Polarizer and second Polarizer is a polyvinyl alcohol (PVA).

3. LCD panel module as claimed in claim 1 is characterized in that, described LCD panel module comprises that more one first protective seam is positioned at the surface of first Polarizer.

4. LCD panel module as claimed in claim 3 is characterized in that, the material of described first protective seam comprises the compound substance or the cyclic olefin of acetic acid three cellophanes, acetic acid three cellophanes and disc-like liquid crystal.

5. LCD panel module as claimed in claim 1 is characterized in that, described LCD panel module comprises that more one second protective seam is positioned at the surface of described second Polarizer.

6. LCD panel module as claimed in claim 5 is characterized in that, the material of described second protective seam comprises the compound substance or the cyclic olefin of acetic acid three cellophanes, acetic acid three cellophanes and disc-like liquid crystal.

7. LCD panel module as claimed in claim 1 is characterized in that, the material of described first glue-line and second glue-line is pressure-sensitive solid or hot-setting adhesive.

8. LCD panel module as claimed in claim 1 is characterized in that, described first thickness h ₁Less than described second thickness h ₂

9. LCD panel module as claimed in claim 8 is characterized in that, described first thickness h ₁Scope between described second thickness h ₂0.1 times to 0.7 times between.

10. LCD panel module, this LCD panel module comprises:

One first substrate;

One second substrate;

One liquid crystal layer is between described first substrate and described second substrate;

One first Polarizer be positioned at the surface of described first substrate, and described first Polarizer has one first coefficient of thermal expansion α ₁

One second Polarizer be positioned at the surface of described second substrate, and described second Polarizer has one second coefficient of thermal expansion α ₂

One is formed at first glue-line between described first Polarizer and described first substrate, and it has one first thickness h ₁And

One is formed at second glue-line between described second Polarizer and described second substrate, and it has one second thickness h ₂,

Wherein, described first thickness h ₁With described second thickness h ₂Identical, and the described first coefficient of thermal expansion α ₁With the described second coefficient of thermal expansion α ₂Different.

11. LCD panel module as claimed in claim 10 is characterized in that, the material of described first Polarizer and second Polarizer is a polyvinyl alcohol (PVA).

12. LCD panel module as claimed in claim 10 is characterized in that, described LCD panel module comprises that more one first protective seam is positioned at the surface of described first Polarizer.

13. LCD panel module as claimed in claim 12 is characterized in that, the material of described first protective seam comprises the compound substance or the cyclic olefin of acetic acid three cellophanes, acetic acid three cellophanes and disc-like liquid crystal.

14. LCD panel module as claimed in claim 10 is characterized in that, described LCD panel module comprises that more one second protective seam is positioned at the surface of described second Polarizer.

15. LCD panel module as claimed in claim 14 is characterized in that, the material of described second protective seam comprises the compound substance or the cyclic olefin of acetic acid three cellophanes, acetic acid three cellophanes and disc-like liquid crystal.

16. LCD panel module as claimed in claim 10 is characterized in that, the material of described first glue-line and second glue-line comprises pressure-sensitive solid or hot-setting adhesive.

17. LCD panel module as claimed in claim 10 is characterized in that, the described first coefficient of thermal expansion α ₁Greater than the described second coefficient of thermal expansion α ₂

18. LCD panel module as claimed in claim 17 is characterized in that, the described first coefficient of thermal expansion α ₁Scope between the described second coefficient of thermal expansion α ₂1.0 times to 5.5 times between.

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