CN1866532A - AC light emitting apparatus and manufacturing method thereof - Google Patents

Abstract

The invention discloses an AC luminous device and making method, which comprises the following parts: base, AC microcrystal grain luminous mode on the base with at least two microcrystals and conductive structure, wherein each microcrystal contains at least two layers of positive layer; the conductive layer connects each microcrystal electrically, which makes each positive layer of each microcrystal with AC positive-to-negative half-wave rotation illumination. The invention can illuminate evenly all the time, which minimizes the bulk of luminous device to produce better light-compositing and all-time luminating effect.

Description

AC illuminator and method for making thereof

Technical field

The invention relates to a kind of light-emitting device, particularly about a kind of AC illuminator and method for making thereof.

Background technology

Be different from the incandescent lamp principle of luminosity, light-emitting diode (Light Emitting Diode, but principle of luminosity LED) mainly is to apply electric current on luminescent substance, reaches illumination effect, so light-emitting diode is called as cold light source (Cold light).Because light-emitting diode has advantages such as durability height, life-span are long, light and handy, power consumption is low, and do not contain harmful substance such as mercury, the solid-state illumination of therefore using LED becomes the important research and development target of following global Lighting Industry and semiconductor industry.Common application direction comprises: display application such as white-light illuminating, indicator light, automobile-used signal lamp and illuminating lamp, flashlight and LED-backlit module, light source of projector, outdoor display.

In illumination was in the past used, most important white light must use a day inferior fluorescent material patent operation just can finish.But for industry, except must the payment patent fee, the white light colour temperature that fluorescent material proportioning and covering process produce is higher can its operation lifetime of reduction, even Yin Wendu is too high and lost efficacy, and the wayward encapsulation of this prior art, has increased the difficulty of volume production.

In addition, the TaiWan, China patent application proposes a kind of ac circuit light emitting diode grain structure that has for No. 093126201.This patent comprises at least: go up at a chip (chip) and form one group of interchange micromeritics light-emitting diode (LED) module, and should exchange the micromeritics light-emitting diode (LED) module by two reverse positive and negative parallel connections of micromeritics light-emitting diode, apply an alternating current, these two micromeritics light-emitting diodes are lighted according to positive and negative half-wave start, forward dc is lighted, is not oppositely lighted in the solution prior art, directly the utilization alternating current significantly improves the application of light-emitting diode as supply of electric power.

But, this patent adopts the planar array design, every tiny crystal grains of light-emitting diode only can be in an ac period forward or luminous under the reverse bias condition, promptly each moment light-emitting area only account for half of chip list area, and the tiny crystal grains in second half area is in resting state, therefore can cause the waste of light-emitting zone.If obtain the brightness of reciprocity whole plane, then current density must be doubled.

Simultaneously because the tiny crystal grains in this patent is the isosceles right triangle shape, and the both sides length of side is being pursued the miniaturization of products, when dwindling the light-emitting diode size, certainly will faced the undersized awkward situation that causes processing difficulties of tiny crystal grains only about 70 microns.In addition, this patent still need be used a day inferior fluorescent material patent, also exist above-mentioned colour temperature higher with problems such as encapsulation control is difficult for.

Therefore, how to develop a kind of various shortcomings that can solve above-mentioned prior art, provide that full-luminous area is can be full-time luminous, uniformly light-emitting, colour temperature is low, colour temperature control has higher overlapping region, need not use the technology of day inferior fluorescent material patent, and can reduce manufacture difficulty and the relative controllability that increases volume production, thereby improve the AC illuminator of industrial utilization, become present problem demanding prompt solution.

Summary of the invention

For overcoming the shortcoming of above-mentioned prior art, main purpose of the present invention is to provide a kind of full-luminous area can full-time luminous AC illuminator and method for making thereof.

Another object of the present invention is to provide a kind of AC illuminator and the method for making thereof that need not use fluorescent material.

But another purpose of the present invention is to provide a kind of AC illuminator and method for making thereof of reduced volume.

But a further object of the present invention is to provide a kind of AC illuminator of uniformly light-emitting.

For realizing above-mentioned and other purpose, the invention provides a kind of AC illuminator, this AC illuminator comprises: a base material; One exchanges the micromeritics light emitting module, is formed on this base material, have two micromeritics at least, and each micromeritics all has two-layer active layers at least; And a conductive structure, electrically connect each micromeritics, make each active layers of each micromeritics can be luminous in turn according to the positive and negative half-wave of alternating current.

Above-mentioned this base material can be selected from a chip or an insulating substrate.This active layers is a luminescence activity layer.This conductive structure comprises that at least being connected between two micromeritics for example is conduction bridge formation conductor.

Electric connection between each active layers of each micromeritics and its comprises connects with in parallel.Each micromeritics can have identical wavelength, thereby sends homochromy monochromatic light; Perhaps each micromeritics has different wavelength, thereby forms the mixed light nonmonochromatic light.Each active layers of this micromeritics can have different wavelength, to form the combination of mixed light white light and nonmonochromatic light.Change according to combinations thereof, can make the same layer active layers of each micromeritics luminous in turn according to the positive and negative half-wave of alternating current, perhaps the different layers active layers of each micromeritics is luminous in turn according to the positive and negative half-wave of alternating current.

In addition, be formed at each micromeritics that has two-layer active layers on the base material at least, can make by flip chip technology (fct) (Flip Chip), chip attach technology (wafer bonding) or crystal technique of heap of stone.

The invention still further relates to a kind of AC illuminator, this AC illuminator comprises: a base material; A plurality of interchange micromeritics light emitting modules are formed on this base material, and each exchanges the micromeritics light emitting module and all has two micromeritics at least, and each micromeritics all has two-layer active layers at least; And a conductive structure, electrically connect respectively and respectively exchange micromeritics light emitting module, each micromeritics, make each active layers of each micromeritics can be luminous in turn according to the positive and negative half-wave of alternating current.

At least one active layers of above-mentioned each micromeritics is arranged according to diode (Diode) circuit structure arrangement mode in the bridge rectifier (Bridge Rectifier), and electrically connects the one or more bridge-type luminescence units of formation mutually.In addition, each bridge-type luminescence unit can be arranged, and the bridge-type luminescence unit quantity of middle section is greater than each peripheral bridge-type luminescence unit quantity.Also can comprise the conductive electrode that is arranged at place, two diagonal angles of arranged, and this conductive electrode connects mutually with each bridge-type luminescence unit, puts alternating-current power supply for connecing.

Corresponding above-mentioned AC illuminator, the present invention also provides two kinds of AC illuminator method for makings, and first kind of method for making comprises: prepare a base material; On this base material, form two-layer active layers at least; Form a plurality of openings in this active layers, expose this base material; Coat a protective layer in this active layers outer rim; Form a plurality of conducting terminals and pass this protective layer, electrically connect mutually with this active layers; And form a plurality of conductive structures at this opening, and electrically connect each active layers, make each active layers after applying alternating current, luminous in turn according to the positive and negative half-wave of this alternating current.

Second kind of method for making comprises: prepare one first base material; On this first base material, form one first active layers; On one second base material, remove this first base material and connect and put this first active layers; On this first active layers, form one second active layers, and between this first active layers and second active layers, form an articulamentum; Form a plurality of openings in this first active layers and second active layers, expose this base material; Coat a protective layer in this first active layers and the second active layers outer rim; Form a plurality of conducting terminals and pass this protective layer, electrically connect mutually with this first active layers and second active layers; And form a plurality of conductive structures at this opening, electrically connect this first active layers and second active layers, make this first active layers and second active layers apply alternating current after, luminous in turn according to the positive and negative half-wave of this alternating current.

Moreover, the invention still further relates to a kind of AC illuminator, this AC illuminator comprises at least: a base material; One bridge-type luminescence unit, this bridge-type luminescence unit comprises: be formed at a plurality of alternating-current light emitting diode micromeritics on this base material, each micromeritics is arranged according to diode circuit structural arrangement mode in the bridge rectifier; And a conductive structure, electrically connect each micromeritics respectively, make each micromeritics can be luminous in turn according to the positive and negative half-wave of alternating current.This AC illuminator also can comprise the bridge-type luminescence unit of a plurality of mutual electric connections, and each bridge-type luminescence unit is arranged, and the bridge-type luminescence unit quantity of middle section is greater than each peripheral bridge-type luminescence unit quantity.The evenly luminous effect of full-luminous area can be provided whereby.In addition, this AC illuminator also comprises: be arranged at the conductive electrode at place, arranged two diagonal angle, and this conductive electrode connects mutually with each bridge-type luminescence unit, puts alternating-current power supply for connecing.

AC illuminator of the present invention utilizes each micromeritics all to have two-layer at least active layers, make each active layers of each micromeritics flow luminous according to the positive and negative impeller of alternating current, realize that full-luminous area can be full-time luminous, luminous equably, do not use simultaneously fluorescent material, and can dwindle the volume of light-emitting device, obtain better mixed light and full-time illumination effect.

Description of drawings

Figure 1A and Figure 1B are the section and the part enlarged diagrams of AC illuminator of the present invention;

Fig. 2 A and Fig. 2 B are the illustrative view of AC illuminator of the present invention;

Fig. 3 A and Fig. 3 B are the equivalent circuit diagrams of Fig. 2 A and Fig. 2 B, have shown the illustrative view of AC illuminator of the present invention;

Fig. 4 is that a plurality of AC illuminator of the present invention is applied in the vertical view on the chip;

Fig. 5 A and Fig. 5 B are another illustrative view of AC illuminator of the present invention;

Fig. 6 A and Fig. 6 B are the equivalent circuit diagrams of Fig. 5 A and Fig. 5 B, have shown another illustrative view of AC illuminator of the present invention;

Fig. 7 is three layers of equivalent circuit diagram of a plurality of AC illuminators of the present invention;

Fig. 8 is the basic circuit diagram that at least one active layers of a plurality of AC illuminator micromeritics of the present invention is arranged according to diode circuit structural arrangement mode in the bridge rectifier;

Fig. 9 A and Fig. 9 B are Fig. 8 circuit structure arrangement modes when being applied in a chip, impose the view of the positive and negative half cycle electric current of alternating current;

Figure 10 A and Figure 10 B are that Fig. 8 circuit structure arrangement mode is considered as a bridge-type luminescence unit, and when being applied in a chip with a plurality of bridge-type luminescence units, impose the view of the positive and negative half cycle electric current of alternating current;

Figure 11 A to Figure 11 D is the circuit diagram of the various execution modes arranged according to diode circuit structural arrangement mode in the bridge rectifier of at least one active layers of a plurality of AC illuminator micromeritics of the present invention;

Figure 12 A to Figure 12 E is the structure flow chart of AC illuminator method for making of the present invention; And

Figure 13 A to Figure 13 F is another structure flow chart of AC illuminator method for making of the present invention.

Embodiment

Embodiment

The present invention discloses a kind of AC illuminator that is applicable on the chip (chip), this AC illuminator produces monochromatic source or white light source or nonmonochromatic source by the alternating current that adds (AC power) and utilizes for the user, and this monochromatic source or nonmonochromatic source find expression in the light output surface of this chip with full-time luminance.Wherein, this alternating current is general civil power, and according to various countries' electrical standard, its voltage is 110V (volt), 100V or 220V, and frequency is 60Hz (hertz) or 50Hz.

Figure 1A and Figure 1B are the structures of representing AC illuminator of the present invention with profile, do the structure explanation with the example of single AC illuminator among the figure.This AC illuminator comprises at least: the interchange micromeritics light emitting module 2 and that a base material 1, is formed on this base material 1 provides the conductive structure 3 that electrically connects effect.

This base material 1 is said chip or insulating substrate, as Al ₂O ₃, GaAs, GaP, SiC etc.

This exchanges micromeritics light emitting module 2 in order clearly to show with accompanying drawing, Figure 1B is an enlarged drawing, it has two micromeritics 20a and 20b at least, and each micromeritics 20a and 20b all have two-layer active layers (last active layers 200a as shown in FIG. and 200b and following active layers 201a and 201b) at least, wherein, this active layers is a luminescence activity layer, and each active layers of this micromeritics 20a and 20b all has other Ohmic electrode 202a, 202b, 203a, 203b, 204a, 204b, 205a and 205b, the alternating current that adds is via this Ohmic electrode 202a, 202b, 203a, 203b, 204a, 204b, 205a and 205b can make this active layers send light source, in addition, be formed at each micromeritics 20a and 20b of having two-layer at least active layers on the base material 1, can pass through flip chip technology (fct) (Flip Chip), chip attach technology (wafer bonding) or crystal technique of heap of stone are made.

This conductive structure 3 electrically connects each micromeritics 20a and 20b, each active layers that makes each micromeritics 20a and 20b is after applying alternating current, can be luminous according to the positive and negative impeller stream of this alternating current, wherein, this conductive structure 3 comprises at least and is connected in two conductor 30b between the micromeritics, conductive structure 3 shown in Figure 1A also comprises: meet the conductor 30a and the 30c that put alternating current, this conductor 30a, 30b and 30c are that a conduction is built bridge.

AC illuminator of the present invention be that example with two AC illuminators explains as flowing mode.Fig. 2 A and Fig. 2 B are the states that applies behind the alternating current.Please cooperate simultaneously shown in Fig. 3 A and Fig. 3 B, it is the equivalent circuit diagram (respectively to should Fig. 2 A and Fig. 2 B) of AC illuminator of the present invention, wherein, each active layers same light-emitting diodes (LED) such as (go up active layers 200 and reach active layers 201 down), have the P/N structure, therefore, the last active layers 200 of each micromeritics 20 and following active layers 201 form the state of connecting, between each micromeritics 20 via conductive structure 3 electric connections, shown in Fig. 3 A and Fig. 3 B, form a state in parallel.

Shown in Fig. 2 A and Fig. 3 A, it is the luminance that the positive half cycle current of this alternating current flows through this AC illuminator, when the positive half cycle current of this alternating current is imported, the last active layers 200 of each micromeritics 20 is forward, positive half cycle current is an arrow as shown in Figure 3A, make on each active layers 200 send light source via the last active layers 200 of each micromeritics 20, when the negative half-cycle current of this alternating current is imported, shown in Fig. 2 B and Fig. 3 B, the following active layers 201 of each micromeritics 20 is forward, negative half-cycle current is the arrow shown in Fig. 3 B, makes each time active layers 201 send light source via the following active layers 201 of each micromeritics 20.Can find out with equivalent circuit diagram of the present invention, the present invention is the positive and negative half cycle electric current that receives alternating current with two light-emitting diodes that are equal to push-down stack, no matter making device of the present invention is when the positive half cycle current of alternating current or negative half-cycle current pass through, light source is sent in the capital, and the same layer active layers of each micromeritics 20 (going up active layers 200 or following active layers 201) is luminous in turn according to the positive and negative half-wave of alternating current.

As shown in Figure 4, when the interlaced arrangement of multiple arrangement of the present invention is applied in a chip and applies alternating current, can make this plane (light output surface of chip) alternately luminous in the mode of frequency 60Hz.Wherein, each micromeritics 20 can be to have identical or different wavelength, the light source that just sends is a color (each active layers also can be to have identical or different wavelength) identical or inequality, if the micromeritics of different wavelength 20, as above active layers is green, following active layers is red, can replace luminous mode because of last active layers reaches following active layers, reaches the effect (ruddiness adds green glow) of mixed light.For example, with wavelength is that 485 to 500nm green glow (going up active layers) collocation wavelength is 580 to 620nm ruddiness (following active layers), and promptly the light of the interlace flicker that sends by last active layers and following active layers is mixed into the effect that is approximately white light (having the many places overlapping with blackbody radiance curve).Therefore, the present invention not only provide a kind of can full-time luminous device, also provide a kind of and can allocate the device (as monochromatic source or nonmonochromatic source) of illuminating source color voluntarily according to user's request, therefore do not need to mix white light source by fluorescent material.

Fig. 5 A and Fig. 5 B are another examples of AC illuminator of the present invention, its equivalent circuit diagram is shown in Fig. 6 A and Fig. 6 B, wherein, each active layers (go up active layers 200c and 200d and active layers 201c and 201d) down such as is at same light-emitting diode, has P/N structure (last active layers 200c and 200d are that P type structure reaches following active layers 201c and 201d is a N type structure), therefore, the last active layers 200c of each micromeritics 20c and 20d and 200d and following active layers 201c and 201d form the state of connecting, and each the micromeritics 20c and the 20d that electrically connect via conductive structure 3 form a state in parallel.

Shown in Fig. 5 A and Fig. 6 A, it is the flow through luminance of this AC illuminator of the positive half cycle current of this alternating current, when the positive half cycle current of this alternating current is imported, the micromeritics 20c adjacent one another are and the active layers of 20d different layers are forward (micromeritics 20c go up active layers 200c and micromeritics 20d and following active layers 201d), positive half cycle current is an arrow as shown in Figure 6A, makes variant layer active layers send light source via the different layers active layers of each micromeritics 20c and 20d; When this alternating current negative half-cycle current input, shown in Fig. 5 B and Fig. 6 B, micromeritics 20c adjacent one another are and the different layers active layers of 20d are forward (micromeritics 20d go up active layers 200d and micromeritics 20c and following active layers 201c), negative half-cycle current is the arrow shown in Fig. 6 B, makes variant layer active layers send light source via the different layers active layers of each micromeritics 20c and 20d.Can find out from equivalent circuit diagram of the present invention, a present invention such as a same example are just receiving alternating current with two light-emitting diodes that are equal to push-down stack, negative half-cycle current, no matter making device of the present invention is when the positive half cycle current of alternating current or negative half-cycle current pass through, light source is sent in the capital, with Fig. 2 A, Fig. 2 B, the example difference of Fig. 3 A and Fig. 3 B is that the different layers active layers of each micromeritics 20c and 20d is luminous in turn according to the positive and negative half-wave of alternating current, but when the interlaced arrangement of multiple arrangement of the present invention is applied in a chip and imposes alternating current, can make that also this plane (light output surface of chip) is full-time luminous.

Above-mentioned each micromeritics 20c and 20d also have identical or different wavelength (each active layers also can be embodied as has identical or different wavelength) as a same example, the light source that just sends is a color identical or inequality, if be embodied as the micromeritics 20c and the 20d of different wavelength, as above active layers 200c and 200d are green, following active layers 201c and 201d are red, then can replace luminous mode (go up active layers 200c → following active layers 201d or go up active layers 200d → following active layers 201c) because of different active layers, (ruddiness adds green glow to reach the effect of mixed light, its mixed light be equal to an example, do not repeat them here).In addition, because the light source that last active layers 200c and 200d and following active layers 201c and 201d send is a color inequality, more can reach the frequency (60Hz * 2) of 120Hz, this glow frequency has surpassed human discernible highest frequency 100Hz, therefore the visual effect that mixed light is come out is more even, and a softer visual effect is provided.Therefore, this example provide a kind of can be full-time luminous, can allocate the device of illuminating source color according to user's request voluntarily, and the light that sends more evenly reaches softly, provides a best visual effect to the user.

If AC illuminator of the present invention is three layers of active layers structure, its execution mode as shown in Figure 7, this figure is an equivalent circuit (active layers is with an above-mentioned and light-emitting diode equivalence), when the alternating current positive half cycle current passes through, as shown by arrows, each active layers that this alternating current positive half cycle current is flowed through all can be luminous (spread to easily in the alternating current negative half-cycle current route of the flowing through path of can positive half cycle current flowing through, and does not repeat them here).The execution mode of this three-decker is that ground floor L1 sends green light source (mixing the colour system that needs most for white light), and second layer L2 sends blue-light source (mix and be the colour system of white light secondary need), and the 3rd layer of L3 sends red light source (mixing the colour system that needs for white light the 3rd).Alternating current positive half wave electric current by the time color be followed successively by blueness, green, green, redness, blueness, green, green, redness; Color when the negative half-wave current of alternating current passes through is blue, green, green, red, blue, green, green, red, therefore, AC illuminator of the present invention can be at alternating current just, the active layers that negative half-cycle current is flowed through utilizes versicolor mutual collocation to reach the mixed light effect, in addition, the structure of these three layers of active layers is if blend together the light source that sends the effect that is approximately white light, its execution mode is the green glow of wavelength 535nm, the ruddiness of the blue light of wavelength 460nm and wavelength 630nm is arranged in pairs or groups mutually, need to prove, if it is actual when making mixed light with these three layers or multilayer active layers, can make colour temperature modulation (certain or some active layers that for example will be wherein makes it can be not luminous in the mode of short circuit) according to actual demand, with realistic mixed light demand.

In addition, as shown in Figure 8, at least one active layers of the micromeritics among the present invention can be arranged according to diode (Diode) circuit structure arrangement mode in the bridge rectifier (Bridge Rectifier), and electrically connect (active layers is with an above-mentioned and light-emitting diode equivalence) between each active layers mutually, its execution mode is the best (color matching modes two-layer and three layers are identical with aforesaid way, do not repeat them here) with mixed light effects two-layer or three layers.

Again as shown in Figure 8, respectively each circuit that electrically connects in the foregoing circuit structural arrangement mode is defined as the first circuit C1, the second circuit C2, tertiary circuit C3, the 4th circuit C4 and the 5th circuit C5 with convenient explanation.Wherein, the glow color and the quantity of each circuit active layers (with the light-emitting diode equivalence) can be arranged in pairs or groups voluntarily according to user's request, its execution mode is that the first circuit C1, the second circuit C2, the 4th circuit C4 and the 5th circuit C5 are provided with 10 active layers of one deck at least respectively, and tertiary circuit C3 is provided with 22 active layers of one deck at least.The active layers number that this circuit structure arrangement mode bears the alternating current reverse bias is about half of alternating current forward bias voltage drop, therefore, when if this structure is born the reverse bias of alternating current simultaneously with a plurality of active layers, can on average bear that (active layers reverse bias that can bear is about 10～15V), so structure can not make the breakdown situation of short circuit that causes of active layers take place because of reverse bias is excessive by each active layers.In addition, if realize white light mixed light effect, please refer to above-mentioned execution mode, the feature of Fig. 8 is except the glow color and quantity of the active layers of can arranging in pairs or groups voluntarily, the second circuit C2 that more the alternating current positive half cycle current can be flowed through, tertiary circuit C3 and the 4th circuit C4 are set to shown in Fig. 9 A, the 5th circuit C5 that in addition the alternating current negative half-cycle current is flowed through, the tertiary circuit C3 and the first circuit C1 are set to shown in Fig. 9 B, the purpose of this circuit is set with the method, just be alternating current, the tertiary circuit that negative half-cycle current all can flow through is seated in the light output surface of a chip, can make this chip light-emitting surface main light emitting conductive electrode E1 and E2 connect put alternating-current power supply after (this conductive electrode E1 and E2 and this circuit electrically connect mutually), have full-time luminous effect.Also just because of no matter the active layers of a plurality of one decks at least of tertiary circuit C3 all can be luminous at positive half cycle of alternating current or negative half period, therefore (with above-mentioned is example can to reduce the quantity that needs active layers in the prior art, active layers of the prior art all needs 22 at the positive and negative half cycle of alternating current, total quantity is 44, and the present invention only needs 22 active layers can reach full-time luminous effect).

Moreover, more above-mentioned active layers (with the light-emitting diode equivalence) circuit structure arrangement mode can be considered as a bridge-type luminescence unit B1 (as shown in Figure 8), just a bridge-type luminescence unit B1 is that at least one active layers of a micromeritics is arranged according to diode circuit structural arrangement mode in the bridge rectifier, and electrically connects mutually.Be arranged on the light output surface (its execution mode is the quantity of the quantity of middle section bridge-type luminescence unit B1 greater than each peripheral bridge-type luminescence unit B1) of a chip with the matrix-style of a plurality of bridge-type luminescence unit B1 shown in Figure 10 A and Figure 10 B, and the confession alternating-current power supply is set at two diagonal angles of this matrix meets conductive electrode E3 and the E4 that puts, (this conductive electrode E3 and E4 and this bridge-type luminescence unit B1 electrically connect mutually with series system), can connect put alternating-current power supply after, make most of zone on this chip light-emitting surface, no matter be all can have electric current to pass through, make it have full-time luminous effect at positive half cycle of alternating current (shown in Figure 10 A) or negative half period (shown in Figure 10 B).

The foregoing circuit structure can be applicable in the AC illuminator that the micromeritics of individual layer active layers constitutes, for example on a base material, form the bridge-type luminescence unit of forming by a plurality of alternating-current light emitting diode micromeritics, each micromeritics is arranged according to diode (Diode) circuit structure arrangement mode in the bridge rectifier (Bridge Rectifier), and electrically connect each micromeritics respectively by a conductive structure, make each micromeritics can be luminous in turn according to the positive and negative half-wave of alternating current.The bridge-type luminescence unit that also can comprise a plurality of mutual electric connections, each bridge-type luminescence unit is arranged, and middle section bridge-type luminescence unit quantity can provide the evenly luminous effect of full-luminous area whereby greater than each peripheral bridge-type luminescence unit quantity.In addition, it also comprises the conductive electrode that is arranged on place, arranged two diagonal angle, and this conductive electrode connects mutually with each bridge-type luminescence unit, puts alternating-current power supply for connecing.Because its circuit structure is same as described above, the accompanying drawing of therefore no longer arranging in pairs or groups is given unnecessary details.

Shown in Figure 11 A, mixed light color (mixed light colour temperature) modulation, also can pass through in tertiary circuit C3 (just permanent bright area, because of the positive and negative half-wave of alternating current all can be by tertiary circuit C3) with at least one active layers of the micromeritics of a plurality of identical wavelength (color) of connecting, realize by electric connection mode parallel with one another again, as shown in FIG., among this tertiary circuit C3 by at least one active layers luminescent line C30 of a plurality of micromeritics that are embodied as ruddiness, be embodied as at least one active layers luminescent line C31 of a plurality of micromeritics of green glow and at least one active layers luminescent line C32 formation parallel with one another that is embodied as a plurality of micromeritics of blue light, like this, can be by the luminescent line C30 of control different colours, the mode of C31 and C32 operating voltage, change the power output of different color light, thereby reach the purpose of control mixed light colour temperature, but, only explain among this embodiment, do not limit actual enforceable quantity and wavelength with example.

But, the execution mode of above-mentioned each luminescent line C30, C31 and C32, also can be shown in Figure 11 B, be embodied as the form that at least one active layers of the micromeritics of a plurality of different wavelength (color) is connected mutually respectively, modulation schemes that also can above-mentioned mixed light colour temperature reaches the purpose of control mixed light colour temperature.

The monochromatic structure of above-mentioned all individual layers is (as Fig. 8, Figure 11 A and Figure 11 B), can quantity at least two and by the electric connection that is superimposed with each other of flip chip or chip attach mode, shown in Figure 11 C, with an individual layer glow color is that the structure F1 of redness and structure F2 that an individual layer glow color is green are superimposed with each other and electrically connect and illustrate, the monochromatic structure of each individual layer (is the structure F2 of green for red structure F1 or individual layer glow color as the individual layer glow color) has two electric connection pad P1 and P2 (placement of electric connection pad and indefinite that electrically connect mutually by flip chip or chip attach mode, as long as can implement), therefore, this mode to be superimposed with each other and to electrically connect, the modulation schemes of all right above-mentioned mixed light colour temperature, reach the purpose of control mixed light colour temperature, and the enforcement quantity of at least one active layers of the micromeritics in the monochromatic structure of each individual layer can be adaptation different color light luminous intensity demand and adjusts.

In addition, among the tertiary circuit C3, can implement again shown in Figure 11 D, electrically connect mutually by parallel way with two active layers of the micromeritics of a plurality of identical or different wavelength (color) luminescent line C33 and C34 that the back forms that connect mutually, modulation schemes that promptly can above-mentioned mixed light colour temperature reaches the purpose of control mixed light colour temperature.

Active layers of the present invention (as above-mentioned and a light-emitting diode equivalence) must applied load can directly not be applied in interlock circuits such as switching circuit or indicator light, and is can a plurality of active layers in parallel or form the lighting apparatus of different application to connect after a plurality of parallel connections again.In addition, this active layers also can be applicable to as in No. the 2005001537th, 2004246696, the U.S., No. 2004333583 disclosed device backlight of patent case of Japan (LCD Backlight).This active layers can be applicable to working procedures again, as 5 Ф LED lead frame jar glue encapsulation make, the encapsulation of Super Flux lead frame jar glue is made, concerned process steps, PPA point glue, the injection of flip-chip, ceramic substrate and aluminium substrate encapsulate and make or the To metal-back encapsulates and makes etc.

The present invention also provides the method for making of the above-mentioned AC illuminator of a kind of correspondence, and shown in Figure 12 A to Figure 12 E, for cooperating above-mentioned example, this method for making also explains with the accompanying drawing of two AC illuminators.Shown in Figure 12 A, this method for making is preparation one base material 1 earlier, and on this base material 1, form two-layer at least active layers (last active layers 200 as shown in FIG. reaches active layers 201 down) successively with crystal type of heap of stone, wherein, this active layers join P type luminescent layer (go up active layers 200) and N type luminescent layer (following active layers 201), this P type luminescent layer and N type luminescent layer are equal to LED P/N structure, and the execution mode of this P type luminescent layer and N type luminescent layer is to be respectively P-InGaN (InGaN) and N-InGaN (InGaN).Then shown in Figure 12 B, form a plurality of openings 4 in this active layers (go up active layers 200 and reach active layers 201 down), expose this base material 1 by yellow light lithography and etching technique.Shown in Figure 12 C, coat a protective layer 5 in this active layers (go up active layers 200 and reach active layers 201 down) outer rim for another example, this protective layer 5 can be avoided electric leakage, and its composition is an electric conducting material, as SiO _xOr SiN _xDeng.Then shown in Figure 12 D, pass this protective layer 5 and form a plurality of conducting terminal 6a, 6b, 6c and 6d, electrically connect mutually with this active layers (go up active layers 200 and reach active layers 201 down).Shown in Figure 12 E, form a plurality of conductive structures 3 each active layers of electric connection (go up active layers 200 and reach active layers 201 down) at last, make each active layers (go up active layers 200 and reach active layers 201 down) luminous in turn according to the positive and negative half-wave of alternating current after energising at this opening 4.This conductive structure 3 comprises the conductor that connects this opening both sides active layers at least.The base material 1 that this method for making is mentioned, active layers (go up active layers 200 and reach active layers 201 down) and conductive structure 3, identical with the execution mode of Fig. 2 A, Fig. 2 B, Fig. 3 A and Fig. 3 B, do not repeat them here.

This conducting terminal 6a, 6b, 6c and 6d form in the evaporation mode, its mode is an Ohmic electrode, form a micromeritics 20 with this active layers (go up active layers 200 and reach active layers 201 down) after electric connection, this micromeritics 20 also has identical or different wavelength as above-mentioned being embodied as.

Shown in Figure 13 A to Figure 13 F, it is the method for making of the corresponding above-mentioned AC illuminator of another kind disclosed by the invention, also cooperates above-mentioned example, with explaining of two AC illuminators.This method for making is preparation one first base material (not marking) earlier, and forms one first active layers 70 on this first base material, removes this first base material again, and as shown in FIG. 13A, connects on one second base material 8 and put this first active layers 70.Then shown in Figure 13 B, form one second active layers 71 on this first active layers 70, and form an articulamentum 72 between this first active layers 70 and second active layers 71, the composition of this articulamentum 72 is electric conducting material and non-conducting material, and is transparent material.Shown in Figure 13 C, form a plurality of openings 9 by yellow light lithography and etching technique for another example, expose this second base material 8 in this first active layers 70 and second active layers 71.Then shown in Figure 13 D, coat a protective layer 10 in the outer rim of this first active layers 70 and second active layers 71, this protective layer 10 can be avoided leaking electricity, and its composition is an electric conducting material, as SiO _xOr SiN _xDeng.Shown in Figure 13 E, pass this protective layer 10 and form a plurality of conducting terminal 6e, 6f, 6g and 6h for another example, electrically connect mutually with this first active layers 70 and second active layers 71.At last shown in Figure 13 F, form a plurality of conductive structures 3 at this opening 9, this conductive structure 3 comprises first active layers and the second active layers conductor that connects these opening both sides at least, electrically connect this first active layers 70 and second active layers 71, make this first active layers 70 and second active layers 71 after applying alternating current, luminous in turn according to the positive and negative half-wave of this alternating current.Second base material 8 that this method for making is mentioned, active layers (first active layers 71 and second active layers 72) and conductive structure 3, the execution mode as Fig. 2 A, Fig. 2 B, Fig. 3 A and Fig. 3 B does not repeat them here.

Conducting terminal 6e, 6f, 6g and the 6h of this method for making such as a same method for making form in the evaporation mode, its execution mode is an Ohmic electrode, itself and this active layers (first active layers 71 and second active layers 72) forms a micromeritics 20 after electric connection, this micromeritics 20 has identical or different wavelength as above-mentioned being embodied as.

In sum, AC illuminator of the present invention utilizes each micromeritics all to have two-layer at least active layers (best example is two-layer or three layers), make each active layers of each micromeritics flow luminous according to the positive and negative impeller of alternating current, reaching full-luminous area can full-time emitting characteristics, and utilize active layers basic structure of the present invention to be applied in different circuit arrangement modes, obtain better mixed light and full-time illumination effect.

Claims (85)

1. an AC illuminator is characterized in that, this AC illuminator comprises:

One base material;

One exchanges the micromeritics light emitting module, is formed on this base material, have two micromeritics at least, and each micromeritics all has two-layer active layers at least; And

One conductive structure electrically connects each micromeritics, makes each active layers of each micromeritics can be luminous in turn according to the positive and negative half-wave of alternating current.

2. AC illuminator as claimed in claim 1 is characterized in that, this base material is a chip.

3. AC illuminator as claimed in claim 1 is characterized in that, this base material is an insulating substrate.

4. AC illuminator as claimed in claim 1 is characterized in that, this active layers is a luminescence activity layer.

5. AC illuminator as claimed in claim 1 is characterized in that, this conductive structure comprises at least and is connected in two conductors between the micromeritics.

6. AC illuminator as claimed in claim 5 is characterized in that, this conductor is that a conduction is built bridge.

7. AC illuminator as claimed in claim 1 is characterized in that, the electric connection mode between each active layers of each micromeritics and its comprises connects with in parallel.

8. AC illuminator as claimed in claim 1 is characterized in that each micromeritics has identical wavelength.

9. AC illuminator as claimed in claim 1 is characterized in that each micromeritics has different wavelength.

10. AC illuminator as claimed in claim 1 is characterized in that, each active layers of this micromeritics has identical wavelength.

11. AC illuminator as claimed in claim 1 is characterized in that, each active layers of this micromeritics has different wavelength.

12. AC illuminator as claimed in claim 1 is characterized in that, each active layers of this micromeritics all has other Ohmic electrode.

13. AC illuminator as claimed in claim 1 is characterized in that, the same layer active layers of each micromeritics is luminous according to the positive and negative impeller stream of alternating current.

14. AC illuminator as claimed in claim 1 is characterized in that, the different layers active layers of each micromeritics is luminous according to the positive and negative impeller stream of alternating current.

15. AC illuminator as claimed in claim 1 is characterized in that, this AC illuminator has each micromeritics of two-layer active layers at least and makes with flip chip technology (fct) or chip attach technology.

16. AC illuminator as claimed in claim 1 is characterized in that, this AC illuminator has each micromeritics of two-layer active layers at least and makes with crystal technique of heap of stone.

17. an AC illuminator is characterized in that, this AC illuminator comprises:

One base material;

A plurality of interchange micromeritics light emitting modules are formed on this base material, and each exchanges the micromeritics light emitting module and all has two micromeritics at least, and each micromeritics all has two-layer active layers at least; And

One conductive structure electrically connects respectively and respectively exchanges micromeritics light emitting module, each micromeritics, makes each active layers of each micromeritics can be luminous in turn according to the positive and negative half-wave of alternating current.

18. AC illuminator as claimed in claim 17 is characterized in that, this base material is a chip.

19. AC illuminator as claimed in claim 17 is characterized in that, this base material is an insulating substrate.

20. AC illuminator as claimed in claim 17 is characterized in that, this active layers is a luminescence activity layer.

21. AC illuminator as claimed in claim 17 is characterized in that, this conductive structure comprise at least be connected in two between the micromeritics light emitting module conductor, be connected in two conductors between the micromeritics.

22. AC illuminator as claimed in claim 21 is characterized in that, this conductor is that a conduction is built bridge.

23. AC illuminator as claimed in claim 17 is characterized in that, each micromeritics light emitting module is connected mutually.

24. AC illuminator as claimed in claim 17 is characterized in that, the electric connection mode between each active layers of each micromeritics and its comprises connects with in parallel.

25. AC illuminator as claimed in claim 17 is characterized in that, each micromeritics has identical wavelength.

26. AC illuminator as claimed in claim 17 is characterized in that, each micromeritics has different wavelength.

27. AC illuminator as claimed in claim 17 is characterized in that, each active layers of this micromeritics all has other Ohmic electrode.

28. AC illuminator as claimed in claim 17 is characterized in that, the same layer active layers of each micromeritics is luminous according to the positive and negative impeller stream of alternating current.

29. AC illuminator as claimed in claim 17 is characterized in that, the different layers active layers of each micromeritics is luminous according to the positive and negative impeller stream of alternating current.

30. AC illuminator as claimed in claim 17 is characterized in that, this AC illuminator has each micromeritics of two-layer active layers at least and makes with flip chip technology (fct) or chip attach technology.

31. AC illuminator as claimed in claim 17 is characterized in that, this AC illuminator has each micromeritics of two-layer active layers at least and makes with crystal technique of heap of stone.

32. AC illuminator as claimed in claim 17 is characterized in that, at least one active layers of each micromeritics is arranged according to diode circuit structural arrangement mode in the bridge rectifier, and electrically connects formation one bridge-type luminescence unit mutually.

33. AC illuminator as claimed in claim 17 is characterized in that, at least one active layers of each micromeritics is arranged according to diode circuit structural arrangement mode in the bridge rectifier, and electrically connects a plurality of bridge-type luminescence units of formation mutually.

34. AC illuminator as claimed in claim 33 is characterized in that, each bridge-type luminescence unit is arranged, and the bridge-type luminescence unit quantity of middle section is greater than each peripheral bridge-type luminescence unit quantity.

35. AC illuminator as claimed in claim 34 is characterized in that, this AC illuminator also comprises the conductive electrode that is arranged on place, arranged two diagonal angle, and this conductive electrode connects mutually with each bridge-type luminescence unit, puts alternating-current power supply for connecing.

36. an AC illuminator method for making is characterized in that, this AC illuminator method for making comprises:

Prepare a base material;

On this base material, form two-layer active layers at least;

Form a plurality of openings in this active layers, expose this base material;

Coat a protective layer in this active layers outer rim;

Form a plurality of conducting terminals and pass this protective layer, electrically connect mutually with this active layers; And

Form a plurality of conductive structures at this opening, electrically connect each active layers, make each active layers after applying alternating current, luminous in turn according to the positive and negative half-wave of this alternating current.

37. AC illuminator method for making as claimed in claim 36 is characterized in that, this base material is a chip.

38. AC illuminator method for making as claimed in claim 36 is characterized in that, this base material is an insulating substrate.

39. AC illuminator method for making as claimed in claim 36 is characterized in that, this active layers is a luminescence activity layer.

40. AC illuminator method for making as claimed in claim 36 is characterized in that, this conductive structure comprises the conductor that connects this opening both sides active layers at least.

41. AC illuminator method for making as claimed in claim 40 is characterized in that, this conductor is that a conduction is built bridge.

42. AC illuminator method for making as claimed in claim 36 is characterized in that, this conducting terminal and this active layers electrically connect the back and form a micromeritics.

43. AC illuminator method for making as claimed in claim 42 is characterized in that each micromeritics has identical wavelength.

44. AC illuminator method for making as claimed in claim 42 is characterized in that each micromeritics has different wavelength.

45. AC illuminator method for making as claimed in claim 42 is characterized in that, each active layers of this micromeritics has identical wavelength.

46. AC illuminator method for making as claimed in claim 42 is characterized in that, each active layers of this micromeritics has different wavelength.

47. AC illuminator method for making as claimed in claim 42 is characterized in that, the same layer active layers of each micromeritics is luminous according to the positive and negative impeller stream of alternating current.

48. AC illuminator method for making as claimed in claim 42 is characterized in that, the different layers active layers of each micromeritics is luminous according to the positive and negative impeller stream of alternating current.

49. AC illuminator method for making as claimed in claim 36 is characterized in that this conducting terminal forms in the evaporation mode.

50. AC illuminator method for making as claimed in claim 36 is characterized in that, this conducting terminal is an Ohmic electrode.

51. AC illuminator method for making as claimed in claim 36 is characterized in that, this AC illuminator method for making forms two-layer active layers with crystal type of heap of stone at least successively on this base material.

52. AC illuminator method for making as claimed in claim 36 is characterized in that, forms a plurality of openings in this active layers with yellow light lithography and etching technique.

53. AC illuminator method for making as claimed in claim 36 is characterized in that, this protective layer composition is an electric conducting material.

54. AC illuminator method for making as claimed in claim 53 is characterized in that this electric conducting material is SiO _xOr SiN _x

55. an AC illuminator method for making is characterized in that, this AC illuminator method for making comprises:

Prepare one first base material;

On this first base material, form one first active layers;

On one second base material, remove this first base material and connect and put this first active layers;

On this first active layers, form one second active layers, and between this first active layers and second active layers, form an articulamentum;

Form a plurality of openings in this first active layers and second active layers, expose this base material;

Coat a protective layer in this first active layers and the second active layers outer rim;

Form a plurality of conducting terminals and pass this protective layer, electrically connect mutually with this first active layers and second active layers; And

Form a plurality of conductive structures at this opening, electrically connect this first active layers and second active layers, make this first active layers and second active layers apply alternating current after, according to the positive and negative half-wave of this alternating current luminous in turn.

56. AC illuminator method for making as claimed in claim 55 is characterized in that, this first base material is a chip.

57. AC illuminator method for making as claimed in claim 55 is characterized in that, this first base material is an insulating substrate.

58. AC illuminator method for making as claimed in claim 55 is characterized in that, this second base material is an insulating substrate.

59. AC illuminator method for making as claimed in claim 55 is characterized in that, this first active layers is a luminescence activity layer.

60. AC illuminator method for making as claimed in claim 55 is characterized in that, this second active layers is a luminescence activity layer.

61. AC illuminator method for making as claimed in claim 55 is characterized in that, this conductive structure comprises first active layers and the second active layers conductor that connects these opening both sides at least.

62. AC illuminator method for making as claimed in claim 61 is characterized in that, this conductor is that a conduction is built bridge.

63. AC illuminator method for making as claimed in claim 55 is characterized in that, this conducting terminal and this first active layers and second active layers electrically connect the back and form a micromeritics.

64., it is characterized in that each micromeritics has identical wavelength as the described AC illuminator method for making of claim 63.

65., it is characterized in that each micromeritics has different wavelength as the described AC illuminator method for making of claim 63.

66., it is characterized in that this micromeritics first active layers has identical wavelength with second active layers as the described AC illuminator method for making of claim 63.

67., it is characterized in that this micromeritics first active layers and second active layers have different wavelength as the described AC illuminator method for making of claim 63.

68., it is characterized in that first active layers of each micromeritics and second active layers are luminous according to the positive and negative impeller stream of alternating current as the described AC illuminator method for making of claim 63.

69., it is characterized in that first active layers of adjacent micromeritics and second active layers are luminous in turn in the mode of different layers according to the positive negative wave of alternating current as the described AC illuminator method for making of claim 63.

70. AC illuminator method for making as claimed in claim 55 is characterized in that this conducting terminal forms in the evaporation mode.

71. AC illuminator method for making as claimed in claim 55 is characterized in that, this conducting terminal is an Ohmic electrode.

72. AC illuminator method for making as claimed in claim 55 is characterized in that, this articulamentum composition is electric conducting material or non-conducting material.

73., it is characterized in that this articulamentum is a transparent material as the described AC illuminator method for making of claim 72.

74. AC illuminator method for making as claimed in claim 55 is characterized in that, forms a plurality of openings in this first active layers and second active layers with yellow light lithography and etching technique.

75. AC illuminator method for making as claimed in claim 55 is characterized in that, this protective layer composition is an electric conducting material.

76., it is characterized in that this electric conducting material is SiO as the described AC illuminator method for making of claim 75 _xOr SiN _x

77. an AC illuminator is characterized in that, this AC illuminator comprises at least:

One base material;

One bridge-type luminescence unit, this bridge-type luminescence unit comprises: be formed at a plurality of alternating-current light emitting diode micromeritics on this base material, each micromeritics is arranged according to diode circuit structural arrangement mode in the bridge rectifier; And

One conductive structure electrically connects each micromeritics respectively, makes each micromeritics can be luminous in turn according to the positive and negative half-wave of alternating current.

78. as the described AC illuminator of claim 77, it is characterized in that, this AC illuminator comprises: the bridge-type luminescence unit of a plurality of mutual electric connections, each bridge-type luminescence unit is arranged, and the bridge-type luminescence unit quantity of middle section is greater than each peripheral bridge-type luminescence unit quantity.

79., it is characterized in that this AC illuminator also comprises as the described AC illuminator of claim 78: be arranged on the conductive electrode at place, arranged two diagonal angle, and this conductive electrode connects mutually with each bridge-type luminescence unit, puts alternating-current power supply for connecing.

80., it is characterized in that this base material is a chip as the described AC illuminator of claim 77.

81., it is characterized in that this base material is an insulating substrate as the described AC illuminator of claim 77.

82., it is characterized in that this active layers is a luminescence activity layer as the described AC illuminator of claim 77.

83., it is characterized in that this conductive structure comprises at least and is connected in two conductors between the micromeritics as the described AC illuminator of claim 77.

84., it is characterized in that this conductor is that a conduction is built bridge as the described AC illuminator of claim 83.

85., it is characterized in that each micromeritics has identical wavelength as the described AC illuminator of claim 77.

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