CN210692587U - LED device and packaging support thereof - Google Patents

Abstract

The utility model discloses a LED device and encapsulation support thereof. This encapsulation support includes: the chip-on-chip type semiconductor device comprises a first metal etching sheet, a second metal etching sheet and a chip placing layer, wherein the first metal etching sheet is stacked with a first electrode and the chip placing layer, and the area of the chip placing layer is larger than that of the first electrode; a second metal etching sheet on which a second electrode and a connection layer are stacked; a first insulation groove is formed between the first electrode and the second electrode, and a second insulation groove is formed between the chip placement layer and the connection layer. Adopt the utility model discloses a LED device and encapsulation support thereof can increase the area of placing the LED chip, and then effectively promote the luminous luminance of LED device.

Description

LED device and packaging support thereof

Technical Field

The utility model relates to a LED technical field especially relates to a LED device and encapsulation support thereof.

Background

In the prior art of LED technology, a package support for packaging an LED chip is basically formed by combining an etching sheet and a reflective cup, wherein, as shown in fig. 1, the etching sheet is usually etched into a first electrode 100 and a second electrode 200 which are separated from each other, the first electrode 100 and the second electrode 200 are both in a flat plate shape, the surface area of the first electrode 100 is larger than that of the second electrode 200, the first electrode 100 is used for fixing the LED chip 101 and is connected to a first end of the LED chip 101, the second electrode 200 is connected to a second end of the LED chip 101, and the reflective cup 400 is formed by injection molding on the etching sheet by using a resin material by an injection molding device.

In order to avoid short circuit when the LED device packaged by the package support is externally connected, the width of the insulation groove 300 between the first electrode 100 and the second electrode 200 on the package support is usually set to be larger, which occupies the area of the package support, so that the placement area for placing the LED chip on the first electrode 100 is smaller, and only one LED chip with a smaller light emitting area can be accommodated, resulting in the problem that the light emitting brightness of the LED device is low.

SUMMERY OF THE UTILITY MODEL

To the above problem, the utility model discloses a LED device and packaging support thereof can increase the area of placing the LED chip, and then promotes the luminous luminance of LED device.

In order to solve the above technical problem, the utility model discloses a packaging support, include: the chip-on-chip type semiconductor device comprises a first metal etching sheet, a second metal etching sheet and a chip placing layer, wherein the first metal etching sheet is stacked with a first electrode and the chip placing layer, and the area of the chip placing layer is larger than that of the first electrode; a second metal etching sheet on which a second electrode and a connection layer are stacked; a first insulation groove is formed between the first electrode and the second electrode, and a second insulation groove is formed between the chip placement layer and the connection layer.

As an improvement of the above solution, the chip placement layer includes a first placement area and a second placement area that are connected to each other, a length of the first placement area is greater than a length of the second placement area, a first end of the first placement area and a first end of the second placement area are flush with each other to form a first edge of the chip placement layer, and a second end of the first placement area and a second end of the second placement area form a second edge of the chip placement layer; the length of the chip placement layer is greater than that of the first electrode, and the width of the chip placement layer is greater than that of the first electrode; the shape of the first edge of the connecting layer is matched with the shape of the second edge of the chip placing layer.

As an improvement of the above scheme, the filler in the second insulation trench includes a first white light reflecting layer; a first containing area is arranged at the second end of the first placing area, a second containing area is arranged at the second end of the second placing area, and the first containing area and the second containing area are mutually connected and arranged in a parallel and staggered manner to form a chip containing area together; and a light reflecting wall is arranged around the rest edge of the chip accommodating area, which is close to the edge of the second insulation groove, and the light reflecting wall is connected with the first white light reflecting layer in the second insulation groove to form a first light reflecting cup.

As an improvement of the above scheme, two parallel edges of the chip accommodating area and the periphery of the edge far away from the second insulation groove are provided with first grooves, and the first grooves are filled with first white light reflecting layers to form the light reflecting walls.

As a modification of the above aspect, the first accommodation region includes a first protrusion located at an end of the first accommodation region next to the second insulation trench; the second accommodating area comprises a second convex part, and the second convex part is positioned at one end of the second accommodating area far away from the second insulation groove.

As an improvement of the above scheme, second reflective cups are arranged around the first metal etching sheet and the second metal etching sheet, and the second reflective cups are located outside the first reflective cups; and a second groove is formed between the first light reflecting cup and the second light reflecting cup and is used for filling a second white light reflecting layer.

As an improvement of the above scheme, the top of the first reflector is square, semicircular or dome-shaped, and the height difference between the top of the first reflector and the top of the first etched metal sheet is 60 μm to 120 μm.

As an improvement of the scheme, the top corners where the second end of the first placing area is connected with the second end of the second placing area are in smooth connection.

As a modification of the above, the first side of the connection layer includes a third convex portion matching the second side of the placement layer, so that the zener diode can be placed at the end of the connection layer.

As an improvement of the above scheme, the chip placement layer further includes a zener connection layer, and the zener connection layer is located between the first reflective cup and the second reflective cup and is close to the third protrusion.

The utility model also provides a LED device, include: two LED chips and any one kind of above-mentioned packaging support, two LED chips set up respectively in first place the district, the second is placed the district.

The utility model also provides a LED device, include: the LED packaging structure comprises two LED chips and the packaging support with the first reflection cup and the second reflection cup, wherein the two LED chips are respectively arranged in the first placing area and the second placing area, the second groove is filled with a second white reflection layer, and fluorescent layers are coated in the first reflection cup and on the second white reflection layer.

Compared with the prior art, implement the utility model discloses a LED device and encapsulation support thereof has following beneficial effect: because the first electrode and the chip placing layer are arranged in a stacked mode in the first metal etching piece, and the area of the chip placing layer is larger than that of the first electrode, the second electrode and the connecting layer are arranged in a stacked mode in the second metal etching piece, on one hand, the packaging support enables the chip placing layer to be made larger by reducing the area of the second insulation groove between the chip placing layer and the connecting layer, so that the packaging support can be used for placing LED chips with larger light-emitting areas, the light-emitting brightness of LED devices made by the packaging support is improved, on the other hand, the width and the area of the first insulation groove between the first electrode and the second electrode can be kept the same as those of the insulation grooves in the prior art, short circuit can be avoided when the packaging support is externally connected, and meanwhile, the packaging support is compatible with the electrodes of the existing packaging support.

Drawings

Fig. 1 is a schematic structural diagram of a package support with LED chips arranged therein in the prior art.

Fig. 2(a) is a schematic bottom view of a package support according to an embodiment of the present invention.

Fig. 2(b) is a schematic top view of a package support according to an embodiment of the present invention.

Fig. 3 is a schematic top view of another package support according to an embodiment of the present invention.

FIG. 4(a) is a schematic layout view of the cross-sectional lines A1-A2, B1-B2, and B1-D, C1-C2 of the package support shown in FIG. 3.

Fig. 4(B) is a cross-sectional view of the package support shown in fig. 3 taken along section line B1-B2.

Fig. 4(c) is a cross-sectional view of the package support shown in fig. 3 taken along section line a1-a 2.

Fig. 4(D) is a cross-sectional view of the package support shown in fig. 3 taken along section line B1-D.

Fig. 4(e) is a cross-sectional view of the package support shown in fig. 3 taken along section line C1-C2.

Fig. 5 is a schematic top view of another package support according to an embodiment of the present invention.

Fig. 6 is a schematic structural diagram of an LED device according to an embodiment of the present invention.

Fig. 7 is a schematic structural diagram of another LED device according to an embodiment of the present invention.

Fig. 8 is a schematic structural diagram of another LED device according to an embodiment of the present invention.

Fig. 9 is a cross-sectional view of a packaged LED device employing the package support of fig. 3 taken along section line B1-B2.

Detailed Description

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. The invention can be embodied in many other forms without departing from the spirit or essential characteristics thereof, and it should be understood that the invention is not limited to the specific embodiments disclosed below.

The technical solution of the present invention will be described in detail and fully with reference to the following embodiments and accompanying drawings.

Fig. 2 is a schematic structural diagram of a package support according to an embodiment of the present invention.

As shown in fig. 2(a) and 2(b), the package support includes: a first metal etching sheet, wherein a first electrode 11 and a chip placing layer 12 are stacked, and the area of the chip placing layer 12 is larger than that of the first electrode 11; a second metal etching sheet on which a second electrode 21 and a connection layer 22 are stacked; a first insulation groove 31 is formed between the first electrode 11 and the second electrode 21, and a second insulation groove 32 is formed between the chip placement layer 12 and the connection layer 22.

In the package support of this embodiment, since the first electrode 11 and the chip placement layer 12 in the first metal etching sheet are stacked and disposed, and the area of the chip placement layer 12 is larger than the area of the first electrode 11, and the second electrode 21 and the connection layer 22 in the second metal etching sheet are stacked and disposed, on one hand, the package support can make the chip placement layer 12 larger by reducing the area of the second insulation groove 32 between the chip placement layer 12 and the connection layer 22, so that the package support can place the LED chip with a larger light emitting area, and improve the light emitting brightness of the LED device manufactured by the package support, on the other hand, because the package support can keep the width and area of the first insulation groove 31 between the first electrode 11 and the second electrode 21 the same as those of the insulation groove in the prior art, it can also avoid short circuit when the package support is externally connected, and simultaneously, the electrode of the packaging bracket can be compatible with the electrode of the existing packaging bracket.

Alternatively, the first electrode 11 and the second electrode 12 may be rectangular and have the same size as the package support in the prior art, so as to be compatible with the package structure of the existing LED device.

In one possible embodiment, as shown in fig. 2(b), the chip placement layer 12 includes a first placement region 121 and a second placement region 122 connected to each other, a length of the first placement region 121 is greater than a length of the second placement region 122, a first end of the first placement region 121 and a first end of the second placement region 122 are disposed flush to form a first edge of the chip placement layer 12, and a second end of the first placement region 121 and a second end of the second placement region 122 form a second edge of the chip placement layer 12; the length of the chip placement layer 12 is greater than that of the first electrode 11, and the width of the chip placement layer 12 is greater than that of the first electrode 11; so, can effectively increase the area that layer 12 was placed to the chip for the second end of first district 121 and the second end crisscross setting of second district 122 of placing is placed to the crisscross two LED chips of placing, promotes the utilization ratio that layer 12 was placed to the chip. In addition, the shape of the first side of the connection layer 22 is matched with the shape of the second side of the chip placement layer 12, so that the connection layer 22 is convex, and the routing and the placement of the Zener diode are performed on the convex part of the connection layer 22.

Alternatively, as shown in fig. 2(b), the first placing area 121 and the second placing area 122 may be integrally formed in a rectangular shape with a protrusion on the upper portion, and the connecting layer 22 is integrally formed in a rectangular shape with a protrusion on the lower portion, so that the first placing area 121 and the upper portion of the connecting layer 22, and the second placing area 122 and the lower portion of the connecting layer 22 can be matched, and the space utilization rate is improved.

Fig. 3 is a schematic structural diagram of another package support according to an embodiment of the present invention.

As shown in fig. 3, in this embodiment, except that the embodiment includes all the structures of the above embodiment, the filler in the second insulation trench 32 includes a first white light-reflecting layer; a first containing area 1211 is arranged at a second end of the first placing area 121, and a second containing area 1221 is arranged at a second end of the second placing area 122, so that the first containing area 1211 and the second containing area 1221 are connected with each other and arranged in a parallel and staggered manner to form a chip containing area together; a reflective wall 13 is disposed around the remaining edge of the chip receiving region immediately outside the edge of the second insulation trench 32, and the reflective wall 13 is connected to the first white reflective layer in the second insulation trench 32 to form a first reflective cup.

In this embodiment, the first containing region 1211 is disposed at the second end of the first placing region 121, the second containing region 1221 is disposed at the second end of the second placing region 122, and the first containing region 1211 and the second containing region 1221 are located at the connection position of the first placing region 121 and the second placing region 122, so that the first containing region 1211 and the second containing region 1221 are connected to each other and parallelly staggered to form a chip containing region, and thus two LED chips are staggered in the chip containing region, and are arranged close to each other, which can improve the utilization rate of the chip placing layer 12; therefore, the light reflecting wall 13 is arranged on the rest of the edge of the chip accommodating area, which is close to the edge of the second insulating groove 32, and the light reflecting wall 13 is connected with the first white light reflecting layer in the second insulating groove 32 to form a first light reflecting cup, the first light reflecting cup can reflect light emitted by the LED chip, and the luminous intensity and the luminous efficiency of the LED device manufactured by adopting the packaging support can be further improved.

Preferably, in the above embodiment, the vertex angle 123 where the second end of the first placing region 121 is connected to the second end of the second placing region 122 is smoothly connected, so that the first white reflective layer in the second insulating trench 32 is uniformly filled, and the uniformity of the light efficiency of the LED device is improved.

In one possible embodiment, as shown in fig. 3, 4(a) -4 (e), the first and second receiving areas 1211 and 1221 may be rectangular areas arranged in a parallel and staggered manner, wherein each of the first and second receiving areas 1211 and 1221 receives one LED chip. Thus, the reflective wall 13 may be formed by closely surrounding the continuous first recess 131 on two parallel sides of the chip accommodating area and the sides thereof away from the second insulation trench 32, and filling the first recess 131 with the first white reflective layer 132. The end of the reflective wall 13 is connected to the first white reflective layer 132 filled in the second insulation trench 32 to form a first reflective cup.

In this embodiment, the joints of the two ends of the first containing area 1211 and the second containing area 1221 are smoothly connected to form two smooth curves outside the chip containing area formed by the first containing area 1211 and the second containing area 1221, so that the first white reflecting layer 132 can be uniformly filled into the reflecting wall 13; so, can promote the utilization efficiency on layer is placed to chip among this encapsulation support, make it not only can increase the area of placing of LED chip, can also leave the space and form the even first anti-light cup of cup wall thickness, promote the light efficiency uniformity of LED device.

Preferably, as shown in fig. 3 to 4, in an embodiment of the present invention, a second reflective cup 4 is surrounded around the first metal etching sheet and the second metal etching sheet, and the second reflective cup 4 is located outside the first reflective cup; a second groove 5 is formed between the first reflective cup and the second reflective cup 4, and the second groove 5 is used for filling a second white reflective layer. Therefore, the reflection efficiency of the LED device manufactured by adopting the packaging support can be further enhanced, and the luminous brightness of the LED device is improved.

Preferably, the top of the first reflector is square, semicircular or dome-shaped, and the height difference between the top of the first reflector and the top of the first etched metal sheet is 60-120 μm.

In addition, as shown in fig. 5, in another possible embodiment, the first accommodation region 1211 may further include a first protrusion 1213, the first protrusion 1213 being located at an end of the first accommodation region 1211 adjacent to the second insulation trench 32; the second accommodation area 1221 may include a second protrusion 1214, and the second protrusion 1214 is located at an end of the second accommodation area 1221 away from the second insulation trench 32. Thus, the reflective wall 13 may include a first reflective wall 1311 and a second reflective wall 1312; the first reflective walls 1311 surround the parallel edges of the first protrusions 1213 and the first receiving areas 1211, and the edges of the first receiving areas 1211 and the second receiving areas 1221 away from the second insulating groove 32, the second reflective walls 1312 surround the parallel edges of the second protrusions 1214 and the second receiving areas 1221, the first ends of the first reflective walls 1311 and the first ends of the second reflective walls 1312 are connected to the white reflective layer in the second insulating groove 32, the second ends of the first reflective walls 1311 and the second ends of the second reflective walls 1312 are staggered, and the outer corners of the second ends of the first reflective walls 1311 are connected to the inner corners of the second ends of the second reflective walls 1312, so that the first reflective cups are formed by the first white reflective layers filled in the first reflective walls 1311, the second reflective walls 1211 and the second insulating groove 32.

Preferably, in the above embodiment, the first side of the connection layer 22 includes the third convex portion 23 matching with the second side of the chip placement layer 12, so that the end of the connection layer 22 can be used for wire bonding and placing zener diode; the chip placement layer 12 further includes a zener connection layer 14, and the zener connection layer 14 is located between the first reflector and the second reflector 4 and close to the third protrusion 23. Because the chip places layer 12 place layer in the first metal etching piece and increases this area through the mode that reduces second insulation trench 32 area, and then can reserve sufficient routing space for zener diode through establishing zener connecting layer 14, simultaneously, set up zener connecting layer 14 and be close to third convex part 23 and be convenient for carry out the routing to zener diode, shorten routing distance.

Preferably, in the present embodiment, the chip placement layer 12 further includes a fourth protrusion 124, and the fourth protrusion 124 is disposed between the first reflective cup and the second reflective cup 4 and is disposed near the first receiving area 1211, so as to reserve a wire bonding space.

Preferably, in the above embodiment, the height of the first reflective cup is smaller than that of the second reflective cup 4, so as to prevent the first reflective cup from blocking the light emitted by the LED chips arranged in the first placement area 121 and the second placement area 122.

Preferably, in the above embodiment, the material of the first white light-reflecting layer 132 may be a white EMC (epoxy molding compound, EMC for short) resin body, so as to improve the light-reflecting efficiency of the LED device manufactured by using the package support, and further improve the light-emitting brightness.

Please refer to fig. 6 to 8, which are schematic structural diagrams of the LED device according to an embodiment of the present invention.

As shown in fig. 2, 6 to 8, the LED device includes: two LED chips and any kind of above-mentioned packaging support, first LED chip 61 in two LED chips sets up in first place district 121, second LED chip 62 in two LED chips sets up in second place district 122.

When the first LED chip 61 and the second LED chip 62 are connected in parallel, a first end of the first LED chip 61 and one end of the second LED chip 62 are connected to the first electrode 11 by being connected to the chip placement layer 12, and a second end of the first LED chip 61 and a second end of the second LED chip 62 are connected to the second electrode 21 by being connected to the connection layer 22.

When the first LED chip 61 and the second LED chip 62 are connected in series, a first end of the first LED chip 61 is connected to the first electrode 11 by being connected to the chip placement layer 12, a second end of the first LED chip 61 is connected to a first end of the second LED chip 62, and a second end of the second LED chip 62 is connected to the second electrode 21 by being connected to the connection layer 22.

In this embodiment, because this encapsulation support makes the chip place layer 12 can make bigger through reducing the area that the chip placed second insulation groove 32 between layer 12 and the articulamentum 22, make this encapsulation support can place the bigger LED chip of luminous area, can effectively promote the luminance of LED device, on the other hand, because of this encapsulation support can keep the width and the area of first insulation groove 31 between first electrode 11 and the second electrode 21 the same with the width and the area homogeneous phase of insulation groove among the prior art, also can avoid the LED device to take place the short circuit when external, simultaneously can also be compatible with the electrode of current LED device.

Preferably, the LED device further includes a zener diode 7, the zener diode 7 is disposed on the connection layer 22, and a first end thereof is connected to the second electrode 21 by being connected to the connection layer 22, and a second end thereof is connected to the first electrode 11 by being connected to the chip placement layer 12. Therefore, reverse breakdown of the LED device can be avoided.

When the packaging support with the first reflecting cup and the second reflecting cup in the embodiment is used for manufacturing the LED device, the LED device comprises two LED chips, the two LED chips are respectively arranged in the first placing area and the second placing area, the second groove is filled with a second white reflecting layer, and fluorescent layers are coated in the first reflecting cup, on the two LED chips and on the second white reflecting layer.

Next, an LED device manufactured by using the package support shown in fig. 3 will be described in detail.

As shown in fig. 3, 7 and 9, the LED device includes two LED devices and a package support having a first reflective cup and a second reflective cup 4, the two LED chips are respectively disposed in a first receiving area 1211 and a second receiving area 1221 of the package support, and a second white reflective layer 8 is filled in a second groove 5 between the first reflective cup and the second reflective cup 4, so that light emitted by the two LED chips by the second white reflective layer 8 is reflected to a light emitting direction of the LED device, thereby increasing the light emitting intensity and the light emitting efficiency of the LED device. In addition, a fluorescent layer 9 is coated in the first reflective cup, on the two LED chips and on the second white reflective layer 8.

Preferably, the top of the first light reflecting cup is square, semicircular or dome-shaped, the height difference between the top of the first light reflecting cup and the top of the first metal etching sheet is 60 to 120 μm, and the height of the second light reflecting cup 4 is higher than that of the first light reflecting cup, so that the surface of the second white light reflecting layer 8 filled in the second groove 5 is a concave arc surface, thereby increasing the reflection area of the LED device and improving the reflectivity of the LED device.

For the embodiment of the LED device of the present invention, since it is fabricated based on the above-mentioned package support, the relevant points can be found in the description of the embodiment of the package support. The LED device embodiments described above are merely illustrative. One of ordinary skill in the art can understand and implement it without inventive effort.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention in any form, so that any simple modification, equivalent change and modification made by the technical entity of the present invention to the above embodiments without departing from the technical solution of the present invention all fall within the scope of the technical solution of the present invention.

Claims (12)

1. A package support, comprising:

the chip-on-chip type semiconductor device comprises a first metal etching sheet, a second metal etching sheet and a chip placing layer, wherein the first metal etching sheet is stacked with a first electrode and the chip placing layer, and the area of the chip placing layer is larger than that of the first electrode;

a second metal etching sheet on which a second electrode and a connection layer are stacked;

a first insulation groove is formed between the first electrode and the second electrode, and a second insulation groove is formed between the chip placement layer and the connection layer.

2. The package support of claim 1, wherein the die attach layer comprises a first attach region and a second attach region that are connected to each other, the first attach region having a length greater than a length of the second attach region, a first end of the first attach region being flush with a first end of the second attach region to form a first edge of the die attach layer, a second end of the first attach region and a second end of the second attach region forming a second edge of the die attach layer; the length of the chip placement layer is greater than that of the first electrode, and the width of the chip placement layer is greater than that of the first electrode;

the shape of the first edge of the connecting layer is matched with the shape of the second edge of the chip placing layer.

3. The package support of claim 2, wherein the filler in the second insulating trench comprises a first white light reflecting layer;

a first containing area is arranged at the second end of the first placing area, a second containing area is arranged at the second end of the second placing area, and the first containing area and the second containing area are mutually connected and arranged in a parallel and staggered manner to form a chip containing area together;

and a light reflecting wall is arranged around the rest edge of the chip accommodating area, which is close to the edge of the second insulation groove, and the light reflecting wall is connected with the first white light reflecting layer in the second insulation groove to form a first light reflecting cup.

4. The package support of claim 3, wherein two parallel edges of the chip accommodating area and the periphery of the edge far away from the second insulation groove are provided with a first groove, and the first groove is filled with a first white reflective layer to form the reflective wall.

5. The package support of claim 3, wherein the first receiving area comprises a first protrusion at an end of the first receiving area proximate to the second isolation trench; the second accommodating area comprises a second convex part, and the second convex part is positioned at one end of the second accommodating area far away from the second insulation groove.

6. The package support according to any one of claims 3 to 5, wherein a second reflector cup is disposed around the first etched metal sheet and the second etched metal sheet, and the second reflector cup is located outside the first reflector cup; and a second groove is formed between the first light reflecting cup and the second light reflecting cup and is used for filling a second white light reflecting layer.

7. The package support of claim 6, wherein the top of the first reflector cup is square, semicircular or dome-shaped, and the height difference between the top of the first reflector cup and the top of the first etched metal sheet is 60 μm to 120 μm.

8. The package support according to any of claims 3 to 5, wherein the corners where the second ends of the first placement areas are connected to the second ends of the second placement areas are smoothly connected.

9. The package support of claim 6, wherein the first side of the connection layer comprises a third protrusion that mates with the second side of the placement layer, such that the end of the connection layer can receive a zener diode.

10. The package support of claim 9, wherein the chip placement layer further comprises a zener connection layer located between the first reflector cup and the second reflector cup and proximate to the third protrusion.

11. An LED device, comprising: the package support of any one of claims 2 to 10 and two LED chips respectively disposed in the first placement region and the second placement region.

12. An LED device, comprising: the packaging support comprises two LED chips and a packaging support according to any one of claims 6-7, wherein the two LED chips are respectively arranged in the first accommodating area and the second accommodating area, the second groove is filled with a second white reflecting layer, and fluorescent layers are coated in the first reflecting cup and on the second white reflecting layer.

Images