CN103943769A - High-power LED lamp with heat radiated through ceramics - Google Patents

Abstract

The invention relates to a high-power LED lamp with heat radiated through ceramics. The high-power LED lamp comprises a ceramic radiating base (6), a circuit board is fixed to one face of the ceramic radiating base (6), a white light LED flip chip (5) is connected to the circuit board, a nontransparent lampshade is fixed to the position above the white light LED flip chip (5), outward-protruding radiating fins (61) are arranged on the other face of the ceramic radiating base (6), and the radiating fins (61) are made of ceramic materials. Due to the fact that the radiating fins and the ceramic radiating base are made of ceramic materials, heat produced by the white light LED flip chip can be rapidly absorbed and radiated through high conductivity and high radiation physical properties of the ceramic materials, it is ensured that the white light LED flip chip is in the constant low temperature state and can work stably and continuously, and therefore the service life of the LED lamp can be prolonged.

Description

A kind of high power LED lamp that uses ceramic heat-dissipating

Technical field

The present patent application is on 02 27th, 2012 applying date, and application number is: 201210044889.4, and name is called the divisional application of the application for a patent for invention of " a kind of high power LED lamp that uses ceramic heat-dissipating ".The present invention relates to a kind of LED light fixture, especially relate to a kind of high power LED lamp that uses ceramic heat-dissipating.

Background technology

LED light fixture is because heat radiation is large, if can not dispel the heat in time, especially great power LED will burn electronic devices and components after of long duration, has influence on that LED light fixture is normal to be used and the life-span.Use heat abstractor on market typically uses heat dissipation metal mode now, but heat dissipation metal does not use the effect of ceramic material heat radiation better.

In addition, using its advantage of Sapphire Substrate is that chemical stability is good, does not absorb visible ray, moderate cost, manufacturing technology relatively ripe, therefore becomes for the most general substrate of GaN growth.In the encapsulation process of LED, all Sapphire Substrate face is directly fixed on heating panel.In the course of work of LED, its luminous zone is the root of device heating.Because Sapphire Substrate itself is a kind of insulating material, and heat conductivility is more poor than GaN material, thus its operating current of LED device of this formal dress is had to certain restriction, to guarantee luminous efficiency and the working life of LED.For improving the heat dispersion of device, people have designed a kind of LED chip structure, the i.e. LED chip of inverted structure.

In addition, the structure of the GaN chip of traditional Sapphire Substrate, electrode is just positioned at the exiting surface of chip.Due to the limited conductivity of p-GaN layer, therefore require the metal level for current spread at p-GaN layer surface precipitation one deck, this current-diffusion layer is made up of Ni and Au, the light splitting of meeting absorbent portion, thus reduce light extraction efficiency.If by flip-chip, current-diffusion layer (metallic reflector) just becomes reflection of light layer so, and light can be launched by Sapphire Substrate like this, thereby improves light extraction efficiency.

After proposing the upside-down mounting design of chip, people have carried out a large amount of research and exploration for its feasibility.Due to the limitation of LED chip design, encapsulation yield is always very low, and reason is as follows: the first, N-type electrode zone is relatively little, is difficult to the respective regions contraposition with pcb board; The second, N-type electrode position is high more a lot of than P type electrode position, is easy to cause rosin joint, sealing-off situation; Three, for making N-type electrode, often to remove artificially active area greatly, reduce so widely the light-emitting area of device, directly affect LED luminous efficiency.

Moreover although the luminous efficiency of LED has exceeded fluorescent lamp and incandescent lamp, commercialization LED luminous efficiency is still lower than sodium vapor lamp (150lm/W).So, does which factor affect the luminous efficiency of LED? with regard to white light LEDs, its encapsulation finished product luminous efficiency is by internal quantum efficiency, electric injection efficiency, and the product of extraction efficiency and packaging efficiency determines.As shown in figure 35, utilize MOCVD, VPE, MBE or LPE technology growth of device (as LED, LD etc.) structure on substrate 30, respectively be from top to bottom substrate 30, n type material layer 31, luminous zone 32, P-type material layer 33, P type electrode 34, P level soldering-tin layer 35, pcb board 36 and heating panel 40.Wherein between n type material layer 31 and heating panel 40, be also connected successively N-type electrode 37, N level soldering-tin layer 38 and pcb board 39.

The technological deficiency that this traditional LED flip-chip exists is as follows:

1, N-type electrode 37 present positions and P type electrode 34 apart from each others in the horizontal direction, the Position Design of the pcb board 39 of N-type electrode 37 to its below has harsh requirement, has influence on encapsulation acceptance rate.

2, N-type electrode 37 positions are more a lot of than P type electrode 34 positions, cause the gap between the pcb board 39 of itself and below larger, are easy to make N level soldering-tin layer 38 long and cause the generation of rosin joint or sealing-off in the time of scolding tin.

3, for N-type electrode 37 and the pcb board 39 of its below can be welded, need to remove luminous zone greatly, have influence on the luminous efficiency of LED chip.

4, electrode zone is large not, affects Injection Current efficiency and then has influence on the luminous efficiency of LED chip.

5, P type electrode and N-type electrode position, in chip both sides, cause electronics flow path to differ, and as Figure 36, form resistance inhomogeneous, and chip light emitting district non-uniform light, has influence on the luminous efficiency of LED chip.

Summary of the invention

The present invention has designed a kind of high power LED lamp that uses ceramic heat-dissipating, and it has solved following technical problem and is:

(1) high-power LED lamp is because heat radiation is large, if can not dispel the heat in time, especially great power LED will burn electronic devices and components after of long duration, has influence on that LED light fixture is normal to be used and the life-span.

(2) N-type electrode district is relative little with P type electrode district, is difficult to and the respective regions contraposition of pcb board, can have influence on the acceptance rate of packaging effect and LED product;

(3) N-type electrode position is high more a lot of than P type electrode position, is easy to cause rosin joint, sealing-off situation;

(4) for making N-type electrode, often to remove artificially active area greatly, reduce so widely the light-emitting area of device, directly affect LED luminous efficiency;

(5) P type electrode and N-type electrode zone are large not, affect Injection Current, have directly affected LED chip luminous efficiency;

(6) P type electrode and N-type electrode position, in chip both sides, cause electronics flow path to differ, and form resistance inhomogeneous, and chip light emitting district non-uniform light has influence on the luminous efficiency of LED chip.

In order to solve the technical problem of above-mentioned existence, the present invention has adopted following scheme:

A kind of high power LED lamp that uses ceramic heat-dissipating, comprise ceramic heat-dissipating pedestal (60), at a fixing circuit board of described ceramic heat-dissipating pedestal (60), be connected with white light LEDs flip-chip (50) at described circuit board, be fixed with a nontransparent lampshade in described white light LEDs flip-chip (50) top, be provided with outwards outstanding radiating fin (61) at the another side of described ceramic heat-dissipating pedestal (60), described radiating fin (61) is also ceramic material, it is characterized in that: described white light LEDs flip-chip (13) layer structure comprises substrate (1) successively, resilient coating (2), N-type layer (3), N-type is limiting layer (4) respectively, luminous zone layer (5), P type is limiting layer (6) respectively, P type layer (7), P type ohmic contact layer (8), light penetrated bed (9), silicon dioxide layer (10), metal level (11), at substrate (1) surface coating one deck nano fluorescent bisque (28), it is characterized in that: this chip is etched into halfpace structure and forms cyclic n nitroso compound type electrode and cylindricality P type electrode, cylindricality P type electrode is by cyclic n nitroso compound type electrodes surrounding, the solder side that described cyclic n nitroso compound type electrode is connected with pcb board with described cylindricality P type electrode is in same level height.

Further, N-type electrode mainly comprises N-type electrode light penetrated bed ito thin film (191) and N-type electrode metal alloy-layer (23), wherein N-type electrode light penetrated bed ito thin film (191) is hierarchic structure, and hierarchic structure bottom is connected with N-type layer (3) exposed region of chip both sides; Hierarchic structure top is connected with N-type electrode metal alloy-layer (23), metal level (11) and dielectric insulating film (16), wherein N-type electrode metal alloy-layer (23) is positioned at the top on hierarchic structure top, and metal level (11) and dielectric insulating film (16) are positioned at the below on hierarchic structure top; P type electrode mainly comprises P type electrode metal alloy-layer (24) and P type electrode light penetrated bed ito thin film (192), P type electrode light penetrated bed ito thin film (192) top is connected with P type electrode metal alloy-layer (24), and P type electrode light penetrated bed ito thin film (192) surrounding extends downward light penetrated bed (9) and metal level (11) and silicon dioxide layer (10) are limited to wherein;

N-type electrode metal alloy-layer (23) is positioned at same level with P type electrode metal alloy-layer (24).

Further, described dielectric insulating film (16) parallels with mid portion and the bottom of hierarchic structure, plays the effect of isolation N-type electrode light penetrated bed ito thin film (191).

Further, in described substrate (1), form one deck male and fomale(M&F) (12).

Further, described substrate (1) passes through male and fomale(M&F) (12) structural transition with described resilient coating (2).

Further, described cyclic n nitroso compound type electrode is connected with radiator structure (26) by pcb board separately with described P type electrode.

Further, above form multiple attachment hole (27) by etching at described substrate (1), nano fluorescent bisque (28) sticks to described substrate (1) surface by described multiple attachment hole (27).

Further, described radiating fin (61) is columned heat radiation projection.

Further, described radiating fin (61) is the heat radiation projection of square shape.

The high power LED lamp of this use ceramic heat-dissipating, compared with common high power LED lamp, has following beneficial effect:

(1) the present invention is because the material of radiating fin and ceramic heat-dissipating pedestal is ceramic material, utilize high conduction and the high radiation physics characteristic of ceramic material, the heat energy that white light LEDs flip-chip can be produced absorbs fast and leaves, guarantee that white light LEDs flip-chip is in a constant low temperature state, and can stablize and continue running, thereby can extend the useful life of LED.

(2) the present invention is owing to adhering to one deck circular nano phosphor powder layer by attachment hole on substrate, and this nano fluorescent bisque is compared with common fluorescent material, and the white light that can make chip send is more bright reliable.

(3) the present invention is due to silicon dioxide layer and the metal level of P type electrode below are wrapped up completely by P type electrode light penetrated bed ito thin film, increase P type electrode light penetrated bed ito thin film exposed area, thereby also just increased light penetrated bed area, improve LED luminous efficiency.

(4) the present invention, because chip structure comprises N-type electrode and P type electrode, makes P electrode and N electrode layer area maximum, obtains maximum Injection Current, improving luminous efficiency.

(5) the present invention, because N-type electrode has adopted hierarchic structure, only requires and removes very little a part of active area, has guaranteed the maximization of reflection layer area, obtains optimal luminescent efficiency.

(6) the present invention, owing to adopting annular N-type electrode layer to surround cylindricality P type electrode layer, can realize the most uniform electric current, makes luminous zone the most even.

(7) the present invention is also because N-type electrode layer and P type electrode layer are in same plane, and encapsulation acceptance rate is higher.

Brief description of the drawings

Fig. 1: LED chip manufacturing process steps 1 schematic diagram in the present invention;

Fig. 2: LED chip manufacturing process steps 2 schematic diagrames in the present invention;

Fig. 3: LED chip manufacturing process steps 3 schematic diagrames in the present invention;

Fig. 4: LED chip manufacturing process steps 4 schematic diagrames in the present invention;

Fig. 5: LED chip manufacturing process steps 5 schematic diagrames in the present invention;

Fig. 6: LED chip manufacturing process steps 6 schematic diagrames in the present invention;

Fig. 7: LED chip manufacturing process steps 7 schematic diagrames in the present invention;

Fig. 8: LED chip manufacturing process steps 8 schematic diagrames in the present invention;

Fig. 9: LED chip manufacturing process steps 9 schematic diagrames in the present invention;

Figure 10: LED chip manufacturing process steps 10 schematic diagrames in the present invention;

Figure 11: LED chip manufacturing process steps 11 schematic diagrames in the present invention;

Figure 12: LED chip manufacturing process steps 12 schematic diagrames in the present invention;

Figure 13: LED chip manufacturing process steps 13 schematic diagrames in the present invention;

Figure 14: LED chip manufacturing process steps 14 schematic diagrames in the present invention;

Figure 15: LED chip manufacturing process steps 15 schematic diagrames in the present invention;

Figure 16: LED chip manufacturing process steps 16 schematic diagrames in the present invention;

Figure 17: LED chip manufacturing process steps 17 schematic diagrames in the present invention;

Figure 18: LED chip manufacturing process steps 18 schematic diagrames in the present invention;

Figure 19: LED chip manufacturing process steps 19 schematic diagrames in the present invention;

Figure 20: LED chip manufacturing process steps 20 schematic diagrames in the present invention;

Figure 21: LED chip manufacturing process steps 21 schematic diagrames in the present invention;

Figure 22: LED chip manufacturing process steps 22 schematic diagrames in the present invention;

Figure 23: LED chip manufacturing process steps 23 schematic diagrames in the present invention;

Figure 24: LED chip manufacturing process steps 24 schematic diagrames in the present invention;

Figure 25: LED chip manufacturing process steps 25 schematic diagrames in the present invention;

Figure 26: LED chip manufacturing process steps 26 schematic diagrames in the present invention;

Figure 27: LED chip manufacturing process steps 27 schematic diagrames in the present invention;

Figure 28: LED chip manufacturing process steps 28 schematic diagrames in the present invention;

Figure 29: LED chip manufacturing process steps 29 schematic diagrames in the present invention;

Figure 30: the present invention uses the high power LED lamp structural representation of ceramic heat-dissipating;

The vertical view of Figure 31: Figure 30;

Figure 32: light reflection hint effect figure in Figure 28;

Figure 33: the present invention uses high power LED lamp and the radiator structure connection diagram of ceramic heat-dissipating;

Figure 34: the present invention uses the high power LED lamp perspective view of ceramic heat-dissipating;

Figure 35: LED chip structural representation in prior art;

Figure 36: in Figure 34, electron stream is to schematic diagram.

Description of reference numerals:

1-substrate; 2-resilient coating; 3-N-type layer; 4-N-type is limiting layer respectively; 5-luminous zone layer; 6-P type is limiting layer respectively; 7-P type layer; 8-P type ohmic contact layer; 9-light penetrated bed; 10-silicon dioxide layer; 11-metal level; 12-male and fomale(M&F); The 13-the first photoresist layer; The 14-the second photoresist layer; The 15-the three photoresist layer; 16-dielectric insulating film; The 17-the four photoresist layer; The 18-the five photoresist layer; 19-light penetrated bed ito thin film; 191-N-type electrode light penetrated bed ito thin film; 192-P type electrode light penetrated bed ito thin film; The 20-the six photoresist layer; 21-metal alloy layer; The 22-the seven photoresist layer; 23-N-type electrode metal alloy-layer; 24-P type electrode metal alloy-layer; 25-pcb board; 26-radiator structure; 27-attachment hole; 28-nano fluorescent bisque;

30-substrate; 31-n type material layer; 32-luminous zone; 33-P-type material layer; 34-P type electrode; 35-P level soldering-tin layer; 36-pcb board; 37-N-type electrode; 38-N level soldering-tin layer; 39-pcb board; 40-heating panel;

50-white light LEDs flip-chip; 51-mounting base; 52-bolt; 60-ceramic heat-dissipating pedestal; 61-radiating fin.

Embodiment

Below in conjunction with Fig. 1 to Figure 34, the present invention will be further described:

As shown in Figure 1, substrate 1 is carrier, is generally the materials such as sapphire, carborundum, silicon, GaAs, AlN, ZnO or GaN.

On substrate 1, first form one deck male and fomale(M&F) 12 with etching, this male and fomale(M&F) 12 can reduce the total reflection of light in chip, increases light emission rate.

Resilient coating 2 is transition zones, on this basis other material such as the N of growing high-quality, P, quantum well.

LED is made up of pn knot, resilient coating 2,3 layers, N-type layer, N-type respectively limiting layer 4, P type limiting layer 6 and P type layer 7 are to make required P and the n type material of LED in order to form respectively.Luminous zone layer 5 is luminous zones of LED, and the color of light is determined by the material of active area.

P type ohmic contact layer 8 is last one decks of Material growth, and the charge carrier doping concentration of this one deck is higher, and object is for making less ohmic contact resistance.

P type metal ohmic contact layer is not formed by growth, but form by methods such as evaporation or sputters, one of object is to make the electrode of device, two of object is to use for packaging and routing.

Again by evaporation, sputter or other film manufacturing method, form one deck ito thin film on P type ohmic contact layer 8 surfaces, for making the light penetrated bed 9 of light-emitting diode, ito thin film is generally tin indium oxide material, be a kind of transparent semiconductor conductive film, generally can make the light extraction efficiency of LED improve 20%-30%.Again by evaporation, sputter or other film manufacturing method, form the completely reflecting mirror of silicon dioxide layer 10 and metal level 11 sandwich constructions at light penetrated bed 9, silicon dioxide layer 10 can improve the current expansion of luminous zone, reduce electric current pile-up effect, and metal level 11 can reduce the absorption of P electrode pair light as speculum, increase the extraction of Sapphire Substrate marginal ray, and can be as the heat-conducting plate of chip; Metal on demand can aluminium, silver or the material such as golden.

As shown in Figure 2, at the metal level 11 surface-coated positive glue of the first photoresist layer 13(or the negative glue of Fig. 1 structure), coating speed is at 2500-5000 rev/min, and between 90 degrees Celsius-100 degrees Celsius of coating temperature controls, in baking oven or iron plate surface baking, baking time is respectively 30 minutes and 2 minutes.

As shown in Figure 3, the first photoresist layer 13 of LED flip-chip periphery is removed by exposure or visualization way, and forms endless metal layer exposed region.

As shown in Figure 4, utilize dry quarter or the method for chemical corrosion, by the N-type of expose portion respectively limiting layer 4, luminous zone layer 5, P type respectively the N-type layer 3 of limiting layer 6, P type layer 7, P type ohmic contact layer 8, light penetrated bed 9, silicon dioxide layer 10, metal level 11 and part remove and make whole LED chip form halfpace structure.

As shown in Figure 5, the first photoresist layer 13 of LED chip intermediate rest is all removed.

As shown in Figure 6, at the surface-coated positive glue of the second photoresist layer 14(or the negative glue of Fig. 5 structure), coating speed is at 2500-5000 rev/min, and between 90 degrees Celsius-100 degrees Celsius of coating temperature controls, in baking oven or iron plate surface baking, baking time is respectively 30 minutes and 2 minutes.

As shown in Figure 7, structural LED flip-chip halfpace part the second photoresist layer 14 is removed by exposure or visualization way, and formed endless metal layer exposed region.

As shown in Figure 8, utilize the method for dry quarter or chemical corrosion, the metal level of expose portion 11 and silicon dioxide layer 10 are removed, form annular groove.

As shown in Figure 9, remaining LED flip-chip the second photoresist layer 14 is all removed.

As shown in figure 10, the surface-coated positive glue of the 3rd photoresist layer 15(or the negative glue of gained LED chip structure in Fig. 9), coating speed is at 2500-5000 rev/min, and between 90 degrees Celsius-100 degrees Celsius of coating temperature controls, in baking oven or iron plate surface baking, baking time is respectively 30 minutes and 2 minutes.

As shown in figure 11, the 3rd photoresist layer 15 on LED chip surface is removed by exposure or visualization way part, formed halfpace outer wall exposed region and on halfpace, form annular exposed region.

As shown in figure 12, utilize PECVD or other coating technique, directly prepare one deck dielectric insulating film 16 at the body structure surface shown in Figure 11, dielectric insulating film 16 materials are silicon dioxide layer or the good dielectric of other light transmission, and thickness is between 100nm-500nm.Dielectric insulating film 16 covers on the LED chip of hierarchic structure and the 3rd photoresist layer 15 surfaces equably by the mode of plated film.

As shown in figure 13, at the LED of Figure 12 body structure surface coating positive glue of the 4th photoresist layer 17(or negative glue), coating speed is at 2500-5000 rev/min, and between 90 degrees Celsius-100 degrees Celsius of coating temperature controls, in baking oven or iron plate surface baking, baking time is respectively 30 minutes and 2 minutes.

As shown in figure 14, the 4th photoresist layer 17 on LED chip surface is removed by exposure or visualization way part, only retained the 4th photoresist layer 17 of halfpace outer wall vertical coating.

As shown in figure 15, utilize the method for dry quarter or chemical corrosion, remove portion dielectric insulating film 16, only retain the dielectric insulating film 16 in annular groove on dielectric insulating film 16 that halfpace outer wall vertical arranges and halfpace, the dielectric insulating film 16 on halfpace in annular groove highly equals the thickness of metal level 11 and silicon dioxide layer 10.

As shown in figure 16, remaining LED chip the 3rd photoresist layer 15 and the 4th photoresist layer 17 are all removed.

As shown in figure 17, at the surface-coated positive glue of the 5th photoresist layer 18(or the negative glue of Figure 16 chip structure), coating speed is at 2500-5000 rev/min, and between 90 degrees Celsius-100 degrees Celsius of coating temperature controls, in baking oven or iron plate surface baking, baking time is respectively 30 minutes and 2 minutes.

As shown in figure 18, the 5th photoresist layer 18 of LED chip annular groove top is removed by exposure or visualization way part, and formed annular dielectric insulating film exposed region.

As shown in figure 19, utilize the method for dry quarter or chemical corrosion, chip top is removed completely by the dielectric insulating film 16 of exposed at both sides part.

As shown in figure 20, remaining LED chip the 5th photoresist layer 18 is all removed.

As shown in figure 21, then pass through evaporation, sputter or other film manufacturing method, on Figure 20 chip structure, form one deck light penetrated bed ito thin film 19, for making light penetrated bed and the conduction of light-emitting diode.

As shown in figure 22, at the surface-coated positive glue of the 6th photoresist layer 20(or the negative glue of Figure 21 chip structure), coating speed is at 2500-5000 rev/min, and between 90 degrees Celsius-100 degrees Celsius of coating temperature controls, in baking oven or iron plate surface baking, baking time is respectively 30 minutes and 2 minutes.

As shown in figure 23, the 6th photoresist layer 20 at LED chip halfpace top is removed by exposure or visualization way part, and formed light penetrated bed ito thin film exposed region.

As shown in figure 24, utilize PECVD or other coating technique, at the chip structure surface preparation layer of metal alloy-layer 21 shown in Figure 23.

As shown in figure 25, at the surface-coated positive glue of the 7th photoresist layer 22(or the negative glue of Figure 24 structure), coating speed is at 2500-5000 rev/min, and between 90 degrees Celsius-100 degrees Celsius of coating temperature controls, in baking oven or iron plate surface baking, baking time is respectively 30 minutes and 2 minutes.

As shown in figure 26, LED chip top is removed by exposure or visualization way part by the 7th photoresist layer 22 of both side surface, retain ring-type and the 7th square photoresist layer 22 at flip-chip halfpace top.And the endless metal alloy-layer exposed region on formation halfpace below and halfpace.In Figure 26, can find out, the 7th remaining photoresist layer 22 is divided into two parts, all be positioned on the step of LED chip, the metal alloy layer exposed region between the 7th photoresist layer 22 of ring-type and the 7th square photoresist layer 22 is isolated for P type electrode and two N-type electrodes.

As shown in figure 27, utilize the method for dry quarter or chemical corrosion, remove the metal alloy layer 21 not covered by the 7th photoresist layer 22, also remove silicon dioxide layer 10, metal level 11 and the light penetrated bed ito thin film 19 between ring-type the 7th photoresist layer 22 and square the 7th photoresist layer 22 simultaneously.Original smooth penetrated bed ito thin film 19 will be divided into N-type electrode light penetrated bed ito thin film 191 and P type electrode light penetrated bed ito thin film 192.

As shown in figure 28, remaining LED chip the 6th photoresist layer 20 and the 7th photoresist layer 22 are all removed, and formed cyclic n nitroso compound type electrode and a P type electrode, P type electrode is by cyclic n nitroso compound type electrodes surrounding.

As shown in figure 29, in order further to improve the luminous efficiency of LED chip, utilize ICP, RIE or other lithographic technique to carry out etching to substrate 1, and form multiple attachment hole 27.

As shown in figure 30, utilize glue spreading method that the nano-phosphor liquid preparing is coated on to substrate 1 surface equably.Then in the baking oven of 100-180 degree Celsius, toast, the time is 10 minutes-1 hour, finally forms the uniform nano fluorescent bisque 28 of one deck on substrate 1 surface.

Till the LED chip in Figure 30, the present invention uses the main making step of the high power LED lamp of ceramic heat-dissipating to complete.

This invention is used the N-type electrode of the high power LED lamp of ceramic heat-dissipating mainly to comprise N-type electrode light penetrated bed ito thin film 191 and N-type electrode metal alloy-layer 23, wherein N-type electrode light penetrated bed ito thin film 191 is hierarchic structure, and hierarchic structure bottom is connected with N-type layer 3 exposed region of chip both sides; Hierarchic structure top is connected with N-type electrode metal alloy-layer 23, metal level 11 and dielectric insulating film 16, and wherein N-type electrode metal alloy-layer 23 is positioned at the top on hierarchic structure top, and metal level 11 and dielectric insulating film 16 are positioned at the below on hierarchic structure top.

The P type electrode of LED chip mainly comprises P type electrode metal alloy-layer 24 and P type electrode light penetrated bed ito thin film 192, P type electrode light penetrated bed ito thin film 192 tops are connected with P type electrode metal alloy-layer 24, and P type electrode light penetrated bed ito thin film 192 surroundings extend downward light penetrated bed 9 and metal level 11 and silicon dioxide layer 10 are limited to wherein; N-type electrode metal alloy-layer 23 is positioned at same level with P type electrode metal alloy-layer 24.

In addition, can find out and comprise through large-area metal level 11, N-type electrode metal alloy-layer 23 and P type electrode metal alloy-layer 24, also can reach heat radiation maximum area.

As shown in figure 31, N-type electrodes surrounding P type electrode, reaches uniform current, and makes luminous zone and illumination effect reach the most uniform perfect condition.

Shown in figure 32, from chip top and both sides four sides bright dipping and metal level 11 reflect, can greatly promote chip light emitting efficiency.

As shown in figure 33, two N-type electrode metal alloy-layers 23 are connected with radiator structure 26 by pcb board 25 respectively with P type electrode metal alloy-layer 24.Because two N-type electrode metal alloy-layers 23 and P type electrode metal alloy-layer 24 positions are in same level, while making they and pcb board 25 soldering, the thickness of soldering layer can effectively be controlled, and avoids rosin joint or sealing-off.

As shown in figure 34, use a high power LED lamp for ceramic heat-dissipating, comprise ceramic heat-dissipating pedestal 60, at a fixing circuit board of ceramic heat-dissipating pedestal 60, be connected with white light LEDs flip-chip 50 at circuit board, above white light LEDs flip-chip 50, be fixed with a nontransparent lampshade; Be provided with outwards outstanding radiating fin 61 at the another side of ceramic heat-dissipating pedestal 60, radiating fin 61 is also ceramic material.Mounting base 51, ceramic heat-dissipating pedestal 6 and radiating fin 61 are fixed by bolt 52.

The present invention is because the material of radiating fin and ceramic heat-dissipating pedestal is ceramic material, utilize high conduction and the high radiation physics characteristic of ceramic material, the heat energy that white light LEDs flip-chip can be produced absorbs fast and leaves, guarantee that white light LEDs flip-chip is in a constant low temperature state, and can stablize and continue running, thereby can extend the useful life of LED.

By reference to the accompanying drawings the present invention is carried out to exemplary description above; obvious realization of the present invention is not subject to the restrictions described above; as long as the various improvement that adopted method design of the present invention and technical scheme to carry out; or without improving, design of the present invention and technical scheme are directly applied to other occasion, all in protection scope of the present invention.

Claims (6)

1. one kind uses the high power LED lamp of ceramic heat-dissipating, comprise ceramic heat-dissipating pedestal (60), at a fixing circuit board of described ceramic heat-dissipating pedestal (60), be connected with white light LEDs flip-chip (50) at described circuit board, be fixed with a nontransparent lampshade in described white light LEDs flip-chip (50) top, be provided with outwards outstanding radiating fin (61) at the another side of described ceramic heat-dissipating pedestal (60), described radiating fin (61) is also ceramic material, it is characterized in that: described white light LEDs flip-chip (13) layer structure comprises substrate (1) successively, resilient coating (2), N-type layer (3), N-type is limiting layer (4) respectively, luminous zone layer (5), P type is limiting layer (6) respectively, P type layer (7), P type ohmic contact layer (8), light penetrated bed (9), silicon dioxide layer (10), metal level (11), at substrate (1) surface coating one deck nano fluorescent bisque (28), described substrate (1) passes through male and fomale(M&F) (12) structural transition with described resilient coating (2), this chip is etched into halfpace structure and forms cyclic n nitroso compound type electrode and cylindricality P type electrode, and cylindricality P type electrode is by cyclic n nitroso compound type electrodes surrounding, and the solder side that described cyclic n nitroso compound type electrode is connected with pcb board with described cylindricality P type electrode is in same level height, described cyclic n nitroso compound type electrode is connected with radiator structure (26) by pcb board separately with described P type electrode.

2. use according to claim 1 the high power LED lamp of ceramic heat-dissipating, it is characterized in that: N-type electrode mainly comprises N-type electrode light penetrated bed ito thin film (191) and N-type electrode metal alloy-layer (23), wherein N-type electrode light penetrated bed ito thin film (191) is hierarchic structure, and hierarchic structure bottom is connected with N-type layer (3) exposed region of chip; Hierarchic structure top is connected with N-type electrode metal alloy-layer (23), metal level (11) and dielectric insulating film (16), wherein N-type electrode metal alloy-layer (23) is positioned at the top on hierarchic structure top, and metal level (11) and dielectric insulating film (16) are positioned at the below on hierarchic structure top; P type electrode mainly comprises P type electrode metal alloy-layer (24) and P type electrode light penetrated bed ito thin film (192), P type electrode light penetrated bed ito thin film (192) top is connected with P type electrode metal alloy-layer (24), and P type electrode light penetrated bed ito thin film (192) surrounding extends downward light penetrated bed (9) and the metal level of below (11) and silicon dioxide layer (10) are limited to wherein; N-type electrode metal alloy-layer (23) is positioned at same level with P type electrode metal alloy-layer (24).

3. the high power LED lamp that uses according to claim 2 ceramic heat-dissipating, is characterized in that: described dielectric insulating film (16) parallels with mid portion and the bottom of hierarchic structure, plays the effect of isolation N-type electrode light penetrated bed ito thin film (191).

4. use according to claim 1 the high power LED lamp of ceramic heat-dissipating, it is characterized in that: above form multiple attachment hole (27) by etching at described substrate (1), nano fluorescent bisque (28) sticks to described substrate (1) surface by described multiple attachment hole (27).

5. the high power LED lamp that uses according to claim 4 ceramic heat-dissipating, is characterized in that: described radiating fin (61) is columned heat radiation projection.

6. the high power LED lamp that uses according to claim 4 ceramic heat-dissipating, is characterized in that: the heat radiation projection that described radiating fin (61) is square shape.