JP3110240U - Wafer level electro-optic semiconductor assembly structure - Google Patents

Abstract

Wafer level electro-optic semiconductor assembly structure that can be implemented with a low-cost configuration and convenient dedicated peripheral automatic equipment, can be used as an application site for electro-optic semiconductor crystal grain sealing products, and has a low cost and high quality effect Provide fine wire and micro-assembly structure.
A wafer having a front surface and a back surface, the front surface of which has a predetermined position 18 for covering crystal grain bonding, and an electro-optic which has a crystal grain contact 11 and is bonded to the predetermined position 18 of the front surface of the wafer 10. A semiconductor crystal grain 12 and a conductive material 13 located in front of the wafer 10 and connecting the electro-optic semiconductor crystal grain 12 and the wafer 10 are included.
[Selection] Figure 2

Description

  The present invention relates to a wafer level electro-optic semiconductor assembly structure, which has the ability to improve the conventional electro-optic semiconductor crystal grain sealing technology, and applies a silver paste and solder paste by a method of applying the paste on the front surface of the wafer. Can be printed on the wafer, screen printing or steel plate printing method, bonding (coating), wire bonding, sealing and dicing, then passed through the conventional crystal grain sealing technology production line, crystal Since the grains are placed on the substrate of the wafer, the performance of the fine line is superior to that of the conventional PCB, and the density of the device can be reduced to improve the device characteristics, and thus the yield rate can be further improved. , Saves man-hour costs, simplifies production process, improves production efficiency, and greatly improves with lower costs It is devised with the results. In particular, the present invention is applied to large-sized light emitting diode crystal grains and sensor sealed production lines.

  As is known in the general related industry, the improvement of the mass production capacity of the electro-optic semiconductor grain sealing production line has been actively researched in various grain sealing related industries and subcontracting agency industries in recent years. When the technical method used there is applicable to, for example, improvement of production flow or use of new materials for various types of crystal grain sealing, the demand for cost reduction and man-hour reduction can be achieved. However, improvement of the production flow is a very important improvement item in the near future, and since the grain sealing equipment is often a precision machine, a slight change always increases the cost. By improving the peripheral flow in accordance with the characteristics, the cost becomes lower and the improvement effect of the production flow is remarkable.

  In the field of IC substrates (including three types of BGA (ball grid array), CSP (chip size package) and flip chip), IC substrates have grown greatly in recent years, and in recent years Taiwan, Korea and China. Actively expanding the production volume of multilayer substrates in continents and other regions, and continuing to invest in laser drilling equipment, increasing the competitiveness in substrate production. Due to the trend of demand for lighter, thinner and smaller portable electronic products in the future, circuit boards have evolved toward thinning and via technology, and in addition to advances in miniature encapsulation technology, the demand for high-quality IC substrates has also improved. As a result, a wide range of advances in small-size grain sealing technology is expected. That is, it is expected that small sized grain seals will continue to evolve again in the future to meet the demands of mobile phone substrates, communications products and the automotive industry.

  FIG. 6 shows a conventional light-emitting diode sealing structure 1a, in which light-emitting diode crystal grains 12a are attached to a base material 10a, connected to a lead wire 14a, and sealed with a sealing material 16a. The conventional light emitting diode sealing structure 1a faces more complicated manufacturing process problems and efficiency (simplifies the process). For example, when pasting a base material, the overall size is too large and the accuracy is insufficient. The volume of the additional circuit (circuit on the substrate) is so large that it affects the sealing dimensions and additional functions during actual application, and also adversely affects the yield rate of sealing. Therefore, it is necessary to study a sealing structure that contributes to the reduction of the sealing dimension and that is easy to add a high function and whose accuracy is easily controlled. In fact, it matches the application requirements. Furthermore, as shown in FIG. 7, when the conventional RGB three-color crystal grains (111-113) emit light and mix white light, the restriction cannot be made thin due to the sealing substrate and circuit design. The RGB three-color crystal grains (111-113) cannot be close to each other, and the distances between the crystal grains are long and dispersed. A similar situation occurs in the photosensor sealing region.

  Therefore, in order to be able to improve the production process and continuously operate with high quality and high efficiency, research on new production flow and new structure corresponding to the actual situation, and on the wafer by printed conductive paste method It is necessary to directly apply a conductive paste by a printing method or to lay out conductive bumps and to paste electro-optic semiconductor crystal grains on the wafer. Then, in the sealed production line, the quality and function of the assembly are improved, but the electro-optic semiconductor crystal grains are pasted on the wafer by applying the paste or the conductive bumps using the pasting method or the printing method. Because the layout is high, the alignment accuracy is high, the cost is low, the cost and the yield rate can be improved, and the production of each peripheral equipment is supported. The present invention can be equipped with the ability to handle various situations and various situations, so the present invention can be studied to achieve the aforementioned requirements. In particular, large-sized electro-optic semiconductors (light-emitting diodes, photosensors and power chips) can be applied to the present invention. Large-sized electro-optic semiconductors can inject required module circuits into the wafer in advance, reducing the volume of the electro-optic device However, other types of blending configurations can accommodate the application of semiconductor crystal grains and coating near the electro-optic semiconductor. In addition, since there is a thermal effect due to heat integration, in the case of a large size, a conventional circuit board (for example, an epoxy board) has a poor heat dissipation effect and has some influence on the life of the product.

  In order to reduce the above-mentioned drawbacks, the inventor submits the present invention which intensively researches and responds to the operation of science, and that the design is rational and extensively and effectively improves the above-mentioned disadvantages.

  That is, the main object of the present invention is to provide a wafer level electro-optic semiconductor assembly structure, i.e. a structure for generating a new production flow method, and a cheaper configuration and corresponding more convenient dedicated peripheral automation equipment. And can be used in an application place of an electro-optic semiconductor crystal grain sealing product, and can provide a low-cost and high-quality effect.

  The next object of the present invention is to provide a wafer level electro-optic semiconductor assembly structure and to provide a fine wire and a micro assembly structure.

  Another object of the present invention is to provide a wafer level electro-optic semiconductor assembly structure, in which necessary module circuits can be injected into the wafer in advance so as to reduce the electro-optic device volume, and a single chip is used as a modular chip. Or can be directly sealed to form a device.

  Still another object of the present invention is to provide a wafer level electro-optic semiconductor assembly structure and to provide good heat dissipation using a wafer substrate.

  In order to achieve the above-mentioned object, the present invention can apply a conductive material to all wafers by a printing method, avoiding problems such as difficulty in reducing the size of a conventional substrate and weakening of circuit function, and an electro-optic semiconductor. Complete crystal grain sealing in response to the use of dedicated equipment for crystal grain sealing, define the crystal grain sealing structure that contributes to actual applications to be more economical, and is more practical than conventional technology Of value. The present invention further has an ESD (Electro Static Discharge) (electrostatic discharge protection) function added protection capability, and further includes functions such as overvoltage protection, voltage stability, current stability, and noise filter. Can be injected into the wafer.

  The structure of the present invention includes a wafer having a front surface and a back surface, the front surface having a predetermined position for covering crystal grain bonding, and an electro-optic that has crystal grain contacts and is bonded to the predetermined position on the front surface of the wafer. A semiconductor crystal grain; and a conductive material positioned in front of the wafer and connecting the electro-optic semiconductor crystal grain and the wafer.

  For a better understanding of the features and technical contents of the present invention, reference is made to the following detailed description of the present invention, which is provided for reference and explanation only and is not intended to limit the present invention. Absent.

The present invention has the following advantages. That is,
1. It is possible to improve alignment accuracy and yield rate. That is, the present invention is implemented by printing a conductive material on a wafer and laminating electro-optic semiconductor crystal grains (light-emitting diodes) on the wafer, thereby reducing alignment errors, and thus improving the yield rate of the unloader. Achieve economic benefits.
2. The sealing dimension can be reduced. That is, electro-optic semiconductor crystal grains (light emitting diodes) are laminated to the wafer, allowing the sealing dimensions of the present invention to be considered wafer level sealing, and the sealing dimensions are smaller.
3. Low cost of process equipment can be achieved. That is, the process is performed appropriately, and it is easy to acquire equipment by reducing the cost of equipment naturally. (For example, equipment for printing conductive paste).
4). The function can be improved. That is, functions can be pre-injected into the integrated circuit on the wafer, for example, increasing the overcurrent to protect the diode.

  The operation principle of the present invention refers to the following description. The present invention is a step in which a conductive paste is printed and applied on a wafer or a gold (or tin) bump is coated, and an electro-optic semiconductor is used to apply crystal grains on a wafer. It is a flow. As a result, the flow of the present invention, which is described in a simple manner, is the production of a wafer, installation of a conductive material, and laminating electro-optic semiconductor crystal grains on the wafer (which can be abbreviated as wire bonding, generally a gold wire) The electro-optic semiconductor crystal grains are easy to position align with the wafer because it is sealing and dicing, and the cumulative alignment error is reduced by printing alignment, contributing to alignment accuracy. It defines a grain-encapsulated production system that contributes to actual application so as to save cost by adding equipment. In addition, a simple voltage stabilization diode (eg, Zener diode) can be provided on the wafer in advance to provide overvoltage protection, current stability, control and noise filter functions, and an antistatic structure can be injected into the wafer. This contributes to improving the function of the entire electro-optic semiconductor.

  The structure of the present invention is such that a wafer having a front surface and a back surface (the front surface of the wafer has a predetermined position for covering crystal grain bonding) and a crystal grain contact are bonded to the predetermined position on the front surface of the wafer. An electro-optic semiconductor crystal grain (which can simply be a power semiconductor or a light-emitting diode) and a conductive material located in front of the wafer. The conductive material connects the electro-optic semiconductor and the wafer. The electro-optic semiconductor can be a light emitting diode or an image sensor.

  According to the above description, the structure of the present invention is to prepare a wafer (10) having a predetermined position (18) for covering crystal grain bonding, and apply a conductive paste (13) (conductive material) to the predetermined position (18). Stacking the electro-optic semiconductor crystal grains (12) (which can be simply a power semiconductor or a light-emitting diode) on the conductive paste (13) of the wafer (10); ) Are sealed with a polymer material to form a semi-finished product, and the semi-finished product after the polymer material is sealed is cut into an assembly structure of electro-optic semiconductor crystal grains.

  Referring to FIG. 1, which is a plan view of a wafer level electro-optic semiconductor assembly structure according to an embodiment of the present invention, the front surface of a wafer (10) has a plurality of electro-optic semiconductor crystal grains (12). Further, referring to FIG. 2, which is a cross-sectional structure for attaching all the electro-optic semiconductor crystal grains (12) and the wafer (10), the front surface has a front surface and a back surface, and the front surface has a predetermined position (18) for flip chip bonding. A wafer (10) having a plurality of flip-chip contacts (11), the electro-optic semiconductor crystal grains (12) being bonded to a predetermined position (18) on the front surface of the wafer (10); A conductive paste (13) located in front of the wafer and connecting the electro-optic semiconductor crystal grains (12) and the wafer (10);

  An embodiment of the present invention will be described in detail with reference to FIGS. In this embodiment, the wafer can have an alignment mark (17). The said conductive paste (13) can be formed by screen printing, can also be formed by steel plate printing, and the thickness of this conductive paste (13) (or conductive material) is 10-50 micrometers. The flip chip contact (11) can be located at the center, edge or entire surface area of the electro-optic semiconductor crystal grains. An overvoltage protection circuit (15) is formed on the front surface of the wafer (10), and is used to prevent overvoltage in parallel with the electro-optic semiconductor crystal grains (12). The overvoltage protection circuit (15 ) Is formed by serially connecting two-phase overvoltage protection diodes (16). The conductive paste (13) is formed of a soldering paste or a silver paste. The electro-optic semiconductor crystal grain (12) is implemented by a light-emitting diode method, and the installation method is a plurality of red, green, and blue three-color crystal grains such as R, G, and B such as ultraviolet and infrared. Can be combined in a specific block (as shown in FIG. 3). In this embodiment, three color crystal grains can be produced by flip-chip method, and a module of RGB crystal grains is directly manufactured, and bonding is performed on a substrate (10 ') by wire bonding method (bonding wire). ) For electrical connection (as shown in FIG. 4). Alternatively, it is directly sealed to be a device (as shown in FIG. 2), and the welded portion (22) is directly provided at the bottom of the wafer, that is, the wafer is directly used as a base material, and there is no need for wire bonding. Alternatively, for example, auxiliary control integrated circuit crystal grains are placed in a certain region to exhibit a polycrystalline grain format (for example, as shown in FIG. 5). The present invention further includes a polymer encapsulating structure (14), allowing the electro-optic semiconductor crystal grain (12) to be surrounded. The method of joining the wafer to the electro-optic semiconductor can be metal eutectic to metal or welded joint of different metals, eg gold eutectic to gold, gold to tin or tin eutectic or weld to tin. Can do.

  Therefore, when a circuit board is used as a sealing mounting board as in the prior art, it is likely to be limited to fine lines, and a finer pitch cannot be achieved (the width between lines of the conventional sealing mounting board is often 0.05 mm. ) If the wafer is used as a mounting plate as in the present invention, the width between the lines can be 0.005 mm or less, the size of the device is greatly reduced, and the light emitting diode has its light emission characteristics. The distance between crystal grains is remarkably reduced to improve the heat resistance, and the heat dissipation of the wafer substrate is better than that of the conventional epoxy resin substrate. Can provide a lifetime.

  The above description is only a preferred embodiment of the present invention, and various modifications for applying the contents of the description or drawings of the present invention so as to ensure the rights of the inventor are similarly considered. It is stated here that it falls within the scope of

It is a top view of the wafer level electro-optic semiconductor assembly structure of the Example of this invention. It is a cross-sectional structure schematic diagram which affixes all the electro-optic semiconductor crystal grains and a wafer of this invention. It is a top view which this invention directly manufactures an RGB crystal grain module. FIG. 3 is a schematic cross-sectional structure diagram in which the present invention directly manufactures an RGB crystal grain module. It is a top view of other examples of the present invention. It is a cross-sectional schematic diagram of the conventional light emitting diode sealing structure. It is a top view of the conventional light emitting diode sealing structure.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Wafer 11 Crystal grain contact 12 Electro-optic semiconductor crystal grain 13 Conductive material 14 Polymer sealing structure 18 Predetermined position 20 Specific block

Claims (7)

In the wafer level electro-optic semiconductor assembly structure, the structure is
A wafer (10) having a front surface and a back surface, the front surface having a predetermined position (18) for covering crystal grain bonding;
An electro-optic semiconductor crystal grain (12) having a crystal grain contact (11) and joining to a predetermined position (18) on the front surface of the wafer (10);
A wafer level electro-optic semiconductor, which is located in front of the wafer (10) and includes the electro-optic semiconductor crystal grains (12) and a conductive material (13) for connecting the wafer (10). Assembly structure.   The wafer level electro-optic semiconductor assembly according to claim 1, wherein the bonding method of the wafer (10) to the electro-optic semiconductor crystal grain (12) is eutectic of metal to metal or welding between different metals. Construction.   The wafer level electro-optic semiconductor assembly structure according to claim 1, wherein the conductive material (13) is formed by screen or steel plate printing.   The wafer level electro-optic semiconductor assembly structure according to claim 1, wherein the crystal grain contact (11) is located at a center, an edge or an entire area of the electro-optic semiconductor crystal grain (12).   The wafer level electro-optic semiconductor assembly structure according to claim 1, wherein the conductive material (13) is formed of a soldering paste or a silver paste.   The electro-optic semiconductor crystal grains (12) are installed in a specific block (20) including a plurality of sets of red, green, and blue colors or RGB light emitting diodes such as ultraviolet rays and infrared rays. 2. The wafer level electro-optic semiconductor assembly structure according to claim 1, wherein The wafer level electro-optic semiconductor assembly structure according to claim 1, further comprising a polymer sealing structure (14) and surrounding the electro-optic semiconductor crystal grains (12).

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