CN2696285Y - Radiation structure of elatroluminescent display element - Google Patents
Radiation structure of elatroluminescent display element Download PDFInfo
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- CN2696285Y CN2696285Y CN 200420049473 CN200420049473U CN2696285Y CN 2696285 Y CN2696285 Y CN 2696285Y CN 200420049473 CN200420049473 CN 200420049473 CN 200420049473 U CN200420049473 U CN 200420049473U CN 2696285 Y CN2696285 Y CN 2696285Y
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- display device
- electroluminescent display
- heat
- graphite linings
- dissipating structure
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Abstract
The radiation structure of elatroluminescent display element of the utility model adheres a black lead layer on the board of the elatroluminescent display element and passes through the black lead layer to combine with an aluminum board layer so as to cause an anisotropic heat conduction function composed of the black lead layer to be formed between the aluminum board layer and the elatroluminescent display element; the heat source of the elatroluminescent display element is quickly conducted to the aluminum board layer for leading out by the black lead layer; the heat source of the aluminum board layer corresponding to the other side of the elatroluminescent display element is caused to be homogeneously distributed on the whole black lead layer so as to prevent the heat source from conducting to the elatroluminescent display element. As a consequence, the purpose of prolonging the service life of the elatroluminescent display element is obtained.
Description
Technical field
The utility model relates to the electroluminescent display device heat dissipation technology that plasma display panel (PDP), active display (OLED) etc. belong to self-emitting display, aims to provide one and effectively prolongs the electroluminescent display device heat-dissipating structure in useful life.
Background technology
Press, the TV of the reflection tubular type of often seeing in the family is called for short CRT now, be to belong to electron excitation display (Cathodoluminescence), its principle is that electron beam quickens because of high pressure, get on the iconoscope that plates one deck phosphor material, electron beam is through magnetic field, makes the path produce deviation and beats on the diverse location of iconoscope, and screen coating one deck fluorescent substance material produces RGB three looks with the tri-barrel electron gun bump respectively.
Because deflecting coil (yoke) is difficult for making electron beam to do significantly deflection, so screen is big more, electron beam just needs longer ranging offset, so the CRT monitor volume is big and the screen camber, though can solve the problem of CRT screen camber with the mode that the electromagnetic lens group is done correction with electron beam, and become so-called whole plane TV; But owing to the big Heavy Weight of CRT volume, take analogy interface, the more harmful vision health of radiation, so do not meet the development trend of following consumer electronics.
Therefore, domestic and international many photoelectricity science and technology dealers are devoted to the exploitation of display of new generation invariably, in the hope of the display of more frivolous, a low radiation can be provided; Wherein, to be tending towards ripe display of new generation then be that plasma display panel (PDP), membrane transistor LCD (Liquid Crystal), active display (OLED) etc. are arranged to technology.
In the middle of display of new generation, because so the liquid crystal of TFT-LCD itself can luminously must not add light source, also owing to need the design of backlight, so the power consumption of TFT-LCD is bigger and heavy than self luminous PDP or OLED's, for light source being evenly distributed in the every nook and cranny of screen, so the assistance of light guide plate will be arranged.Add TFT-LCD 30 cun still too high with Heaven size product cost, have on color saturation, visual angle, answer speed and the brightness problem to be overcome, so the large scale product is more competitive with PDP TV in a short time.
As shown in Figure 1, be in the streets being seen at present plasma display panel (PDP, PlasmaDisplay Panel) basic composition configuration diagram, its plasma display panel is based on an electroluminescent display device 10, and its electroluminescent display device 10 is inert gas injecting or mercury gas in the discharge space (that is vacuum glass space) that two face glasss 11 are constituted, and then through drive circuit 20 alive modes, make discharge space gas inside generation discharge (electricity slurry effect just) and discharge ultraviolet, shine the fluorescent material 12 that is coated on face glass 11 walls by ultraviolet light, make fluorescent material 12 be inspired visible light, so as to reaching " self-luminous " display effect.
That is, as long as the fluorescent material that coating is different, will inspire the visible light of different colours, so PDP gets together hundreds thousand of the fluorescent tubes (discharge space just) that dwindle, in each discharge space, inject then and be mixed with neon (Ne) and xenon (Xe), or the inert gas that mixes with xenon (Xe) of helium (He), and coating is red in these hundreds thousand of discharge spaces, blue, green trichromatic fluorescent material, cooperate drive circuit to make the gas of these hundreds thousand of discharge spaces produce electric discharge phenomena, send ultraviolet, excite the fluorescent material that is coated on the discharge space inwall to make it produce visible light, see through suitable image signal again and handle, just three primary colors can be mixed into colored image.
Yet, because " self-luminous " display mode of PDP, might be subjected to the temperature effect that light source produces and reduce the usefulness of display, the effect that therefore must see through heat-dissipating structure make the thermal source of electroluminescent display device be shed to avoid and cause wearing out of electroluminescent display device because of the effect of temperature, as shown in Figure 1, the present known radiator structure of electroluminescent display device 10, it mainly is the aluminum layer 40 that the panel at electroluminescent display device 10 utilizes heat-conducting layer 30 to cohere, the light source that electroluminescent display device 10 is produced with the conduction of heat of utilizing heat-conducting layer 30 is passed to aluminum layer 40 and sheds, but comprise power supply unit owing to correspond to electroluminescent display device 10 other sides at aluminum layer 50, drive circuits such as integrated circuit 20 also can produce thermal source, its thermal source can see through aluminum layer 40 equally, heat-conducting layer 30 is back to electroluminescent display device 10, not only can the radiating effect of electroluminescent display device 10 be impacted, can therefore cause the temperature Centralized of electroluminescent display device 10 even, become the factor that electroluminescent display device 10 wears out on the contrary.
The utility model content
The heat-dissipating structure of the utility model electroluminescent display device, its heat-dissipating structure is that the plate face at electroluminescent display device attaches a graphite linings, seeing through graphite linings again combines with aluminum layer, so that form one between electroluminescent display device and the aluminum layer by anisotropy conduction of heat that graphite linings constituted, the thermal source of electroluminescent display device is conducted to the aluminum layer derivation fast by graphite linings, and make aluminum layer correspond to other thermal source of side of electroluminescent display device and be dispersed in whole graphite linings, be passed to electroluminescent display device with the blocking-up thermal source, prolong the electroluminescent display device purpose in useful life to reach.
Moreover, its graphite linings is can see through heat conduction aluminium foil double faced adhesive tape to combine with the electroluminescent display device formation, certainly also can see through heat conduction aluminium foil double faced adhesive tape and constitute combining of graphite linings and aluminum layer, simplifying the procedure of processing of integral heat sink structure, and then the production capacity of lifting self-emitting display.
The technical solution of the utility model is:
A kind of heat-dissipating structure of electroluminescent display device, wherein: this heat-dissipating structure is that the plate face at electroluminescent display device attaches a graphite linings with heat conduction aluminium foil double faced adhesive tape, high-temperature plastic band edge sealing is sentenced in the edge of this graphite linings, combine with aluminum layer with graphite linings again, by the anisotropy conduction of heat that graphite linings constituted, the thermal source of electroluminescent display device is conducted to aluminum layer fast by graphite linings derives, and make aluminum layer correspond to electroluminescent display device in addition the thermal source of side be dispersed in whole graphite linings.
This graphite linings is to see through heat conduction aluminium foil double faced adhesive tape to combine with the aluminum layer formation.
This graphite linings is to see through heat conduction aluminium foil double faced adhesive tape to combine with the electroluminescent display device formation, and this aluminum layer is to see through heat conduction aluminium foil double faced adhesive tape to combine with the graphite linings formation.
Electroluminescent display device is inert gas injecting or a mercury gas in the discharge space that two face glasss are constituted, and is coated with fluorescent material at the face glass wall of discharge space inside.
The discharge space of this electroluminescent display device is to inject the inert gas that is mixed with neon Ne and xenon Xe.
The discharge space of this electroluminescent display device is to inject the inert gas that is mixed with helium He and xenon Xe.
In the discharge space of this electroluminescent display device the fluorescent material of coating Red.
Description of drawings
Fig. 1 is the radiator structure schematic diagram of known electroluminescent display device;
Fig. 2 is the electroluminescent display device heat-dissipating structure schematic diagram of the utility model first embodiment;
Fig. 3 is the surface structure schematic diagram of graphite linings of the present utility model;
Fig. 4 is the electroluminescent display device heat-dissipating structure schematic diagram of the utility model second embodiment.
[figure number explanation]
10 electroluminescent display devices, 40 aluminum layers
11 face glasss, 50 graphite linings
12 fluorescent material, 51 high temperature resistant adhesive tapes
20 drive circuits, 60 heat conduction aluminium foil double faced adhesive tapes
30 heat-conducting layers
Embodiment
For the clear structure of the present utility model of your auditor is formed, and the overall operation mode, cooperate graphic being described as follows now:
The heat-dissipating structure of the utility model electroluminescent display device, the basic structure of its integral heat sink structure is formed as shown in Figure 2, is that the plate face at electroluminescent display device 10 attaches a graphite linings 50, sees through graphite linings 50 again and combines with aluminum layer 40.
In the present embodiment, electroluminescent display device 10 is to be " self-luminous " display element of plasma display panel (PDP, Plasma Display Panel), and it is inert gas injecting or a mercury gas in the discharge space that two face glasss 11 are constituted; Wherein, discharge space is can inject to be mixed with the inert gas that neon (Ne) and xenon (Xe) or helium (He) mix with xenon (Xe), and the fluorescent material of coating Red in the discharge space, and then through drive circuit 20 alive modes, making the discharge space gas inside produce electricity starches discharge effect and discharges ultraviolet, shine the fluorescent material 12 that is coated on face glass 11 walls by ultraviolet light, make fluorescent material 12 be inspired visible light, so as to reaching " self-luminous " display effect.
Please cooperate three simultaneously according to shown in Figure 3, emphasis of the present utility model, it promptly is the anisotropy conduction of heat (Anisotropic) that formation one is made of graphite linings 50 between electroluminescent display device 10 and aluminum layer 40, the anisotropy thermal conduction characteristic of the graphite linings 50 of its en plaque be for the coefficient of heat conduction that can make thickness H direction be 7W/M.K, and the coefficient of heat conduction of flat transverse L direction is the extreme otherness of 240W/M.K, and wherein high-temperature plastic band 51 edge sealing are sentenced in the edge of graphite linings 50, in order to avoid the graphite in the graphite linings 50 drops.
Therefore, can make the thermal source of electroluminescent display device 10 conduct to aluminum layer 40 derivation fast by graphite linings 50, and make aluminum layer 40 correspond to electroluminescent display device 10 in addition the thermal source that produced of the drive circuit 20 of side be dispersed in whole graphite linings 50, be passed to electroluminescent display device 10 with the blocking-up thermal source, and effectively prolonged the useful life of electroluminescent display device 10.
Again, in embodiment as shown in Figure 2, graphite linings 50 is can see through heat conduction aluminium foil double faced adhesive tape 60 to combine with electroluminescent display device 10 formations, certainly also can be as shown in Figure 4, see through heat conduction aluminium foil double faced adhesive tape 60 and constitute combining of graphite linings 50 and aluminum layer 40, with the procedure of processing of simplification integral heat sink structure, and then the production capacity of lifting self-emitting display.
And and for example shown in Figure 3, the graphite linings 50 of this en plaque is pasted with high temperature resistant adhesive tape 51 in the edge of its plate, and with four peripheral regions of graphite linings 50 edge sealing in addition, in order to avoid the graphite in the graphite linings 50 drops out, influences the quality of active display.
As mentioned above, the utility model provides plasma display panel (PDP), active display another preferable feasible electroluminescent display device heat-dissipating structures of self-emitting display such as (OLED), so, offer the application of utility model patent in accordance with the law; Yet; above implementation and graphic shown in; it is one of the utility model preferred embodiment; be not to limit to the utility model with this; therefore; all all and the utility model structure, device, feature etc. are approximate, identical, all should belong within the protection range of founding purpose and applying for a patent of the present utility model.
Claims (7)
1, a kind of heat-dissipating structure of electroluminescent display device, it is characterized in that: this heat-dissipating structure is that the plate face at electroluminescent display device attaches a graphite linings with heat conduction aluminium foil double faced adhesive tape, high-temperature plastic band edge sealing is sentenced in the edge of this graphite linings, combine with aluminum layer with graphite linings again, by the anisotropy conduction of heat that graphite linings constituted, the thermal source of electroluminescent display device is conducted to aluminum layer fast by graphite linings derives, and make aluminum layer correspond to electroluminescent display device in addition the thermal source of side be dispersed in whole graphite linings.
2, the heat-dissipating structure of electroluminescent display device as claimed in claim 1 is characterized in that: this graphite linings is to see through heat conduction aluminium foil double faced adhesive tape to combine with the aluminum layer formation.
3, the heat-dissipating structure of electroluminescent display device as claimed in claim 1, it is characterized in that: this graphite linings is to see through heat conduction aluminium foil double faced adhesive tape to combine with the electroluminescent display device formation, and this aluminum layer is to see through heat conduction aluminium foil double faced adhesive tape to combine with the graphite linings formation.
4, the heat-dissipating structure of electroluminescent display device as claimed in claim 1, it is characterized in that: electroluminescent display device is inert gas injecting or a mercury gas in the discharge space that two face glasss are constituted, and is coated with fluorescent material at the face glass wall of discharge space inside.
5, the heat-dissipating structure of electroluminescent display device as claimed in claim 4 is characterized in that: the discharge space of this electroluminescent display device is to inject the inert gas that is mixed with neon Ne and xenon Xe.
6, the heat-dissipating structure of electroluminescent display device as claimed in claim 4 is characterized in that: the discharge space of this electroluminescent display device is to inject the inert gas that is mixed with helium He and xenon Xe.
7, the heat-dissipating structure of electroluminescent display device as claimed in claim 4 is characterized in that: the fluorescent material that in the discharge space of this electroluminescent display device is the coating Red.
Priority Applications (1)
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CN 200420049473 CN2696285Y (en) | 2004-04-27 | 2004-04-27 | Radiation structure of elatroluminescent display element |
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CN 200420049473 CN2696285Y (en) | 2004-04-27 | 2004-04-27 | Radiation structure of elatroluminescent display element |
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN100432794C (en) * | 2005-06-13 | 2008-11-12 | 三星电子株式会社 | Liquid crystal display device having improved cooling efficiency |
CN103763892A (en) * | 2014-01-26 | 2014-04-30 | 斯迪克新型材料(江苏)有限公司 | Heat conduction graphite patch for microelectronic device |
CN104976597A (en) * | 2014-04-10 | 2015-10-14 | 株式会社唻迪克世 | Led lamp heat radiation structure using mechanical alloying method and manufacturing method thereof |
CN109678354A (en) * | 2017-10-18 | 2019-04-26 | 天津北玻玻璃工业技术有限公司 | Edge bonding method before a kind of doubling glass plated film |
-
2004
- 2004-04-27 CN CN 200420049473 patent/CN2696285Y/en not_active Expired - Fee Related
Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN100432794C (en) * | 2005-06-13 | 2008-11-12 | 三星电子株式会社 | Liquid crystal display device having improved cooling efficiency |
CN103763892A (en) * | 2014-01-26 | 2014-04-30 | 斯迪克新型材料(江苏)有限公司 | Heat conduction graphite patch for microelectronic device |
CN106332521A (en) * | 2014-01-26 | 2017-01-11 | 斯迪克新型材料(江苏)有限公司 | Manufacturing method for double-sided adhesive graphite flake |
CN103763892B (en) * | 2014-01-26 | 2017-01-11 | 斯迪克新型材料(江苏)有限公司 | Heat conduction graphite patch for microelectronic device |
CN106535560A (en) * | 2014-01-26 | 2017-03-22 | 斯迪克新型材料(江苏)有限公司 | Manufacturing process for heat-conducting graphite paste films for flat computers |
CN104976597A (en) * | 2014-04-10 | 2015-10-14 | 株式会社唻迪克世 | Led lamp heat radiation structure using mechanical alloying method and manufacturing method thereof |
CN109678354A (en) * | 2017-10-18 | 2019-04-26 | 天津北玻玻璃工业技术有限公司 | Edge bonding method before a kind of doubling glass plated film |
CN109678354B (en) * | 2017-10-18 | 2021-12-14 | 天津北玻玻璃工业技术有限公司 | Edge sealing method before film coating of laminated glass |
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C19 | Lapse of patent right due to non-payment of the annual fee | ||
CF01 | Termination of patent right due to non-payment of annual fee |