KR20230174805A - Semiconductor Package With Embedded Thermal Conductive Member And Manufacturing Method Of The Same AND Induction Heating Soldering Apparatus - Google Patents

Abstract

The present invention relates to a heat-dissipating semiconductor package with an embedded heat-conducting member and a method of manufacturing the same. The heat-conducting member, which is a heat-dissipating means for dissipating heat generated inside the semiconductor package to the outside, is embedded in a molding part forming the outer shape of the semiconductor package. ) to achieve optimal heat conduction within the minimum thickness of the molding part of the semiconductor package.

Description

Heat dissipation semiconductor package with embedded heat conductive member, manufacturing method thereof, and induction heating soldering apparatus used for manufacturing the same {Semiconductor Package With Embedded Thermal Conductive Member And Manufacturing Method Of The Same AND Induction Heating Soldering Apparatus}

The present invention relates to semiconductor packages and, in particular, to semiconductor packages including heat dissipation technology through heat-conducting members and their manufacturing.

A semiconductor package is made by mounting a semiconductor chip on a substrate, and molding a single module with a thermosetting material such as EMC (Epoxy molding compound) to connect the semiconductor chip and lead frame with a bonding flip chip or bonding wire to form the package body (molding part). ) is formed by forming.

As shown in Figure 8, semiconductor package manufacturing is produced through eight representative processes. First, the wafer, which becomes the base of the integrated circuit, is made of very high purity single crystal silicon (SiO2) and is manufactured as an ingot and then cut to be used as a wafer. After the oxidation process, a photo process (sensitization, exposure, development) is performed on the wafer, followed by an etching process, and a circuit pattern is implemented through thin film deposition and metal wiring processes. A multi-layer circuit is implemented by repeating this process according to the layered structure. Afterwards, it goes through an EDS process to check whether individual semiconductor chips have reached the desired quality level through electrical characteristic inspection. When a certain quality is reached through the EDS process, a path is created so that the semiconductor chip can exchange signals with the outside world, and it goes through a packaging process in which epoxy resin is discharged and hardened on the semiconductor chip to protect it from various external environments.

At this time, the final product produced through the packaging process is called a semiconductor package.

Early semiconductor packages were called SSI (small-scale integration), a small-scale integrated circuit containing only a few transistors, later MSI (Middle Scale Integration) containing hundreds of transistors, and later LSI (Large Scale Integration) containing tens of thousands of transistors. Integration). Currently, VLSI (Very Large Scale Integration) is being developed into large-scale semiconductor chips containing 10,000 to 1,000,000 transistors.

ULSI (Ultra-Large-Scale Integration), which reflects the continued increase in complexity, is an ultra-large-scale integration of semiconductor chips containing more than a million transistors and computers and other systems such as SOC (System-On-a-Chip). Integrated circuits containing all the necessary elements on one chip are being developed and manufactured.

In this way, as semiconductor technology becomes more advanced, the speed of semiconductor chips increases, and the functions increase, the problem of heat generation becomes more and more serious, and the thermal dissipation function of the semiconductor package becomes very important.

As a conventional heat dissipation technology for semiconductor packages, a technology of attaching a heat sink directly to the surface of the package body (hereinafter referred to as a molding portion) is widely used. In the semiconductor package according to the prior art, heat generated from the semiconductor chip is transferred to the heat sink through a molding part made of plastic and is emitted to the outside.

However, the plastic material that makes up the molding part not only has low thermal conductivity, but also does not emit much heat through the heat sink attached to the molding part due to the thickness of the molding part itself.

Another heat dissipation technology for semiconductor packages includes a technology for attaching a sheet (TIM sheet) containing a thermally conductive interface material (TIM) to a molding portion, as shown in FIG. 1. However, because these TIM sheets are also attached to the surface of the molding part, heat dissipation is still not large. In addition, the TIM sheet is attached to the molding part through self-adhesive force or adhesive, but after a long period of time, the adhesive strength weakens and the TIM sheet easily falls off from the molding part, which reduces the heat conduction effect.

Korean Patent Publication No. 10-2021-0143224 Korean Patent Publication No. 10-2021-0096497

The present invention was developed to solve the problems of the prior art described above. The present invention provides an improved semiconductor by preventing malfunction and damage to the semiconductor chip due to overheating by providing a heat dissipation structure for the semiconductor package to effectively dissipate heat generated from the semiconductor chip. The purpose is to provide a semiconductor package and manufacturing method that can implement chip performance.

A heat dissipation semiconductor package according to the present invention for solving the above problems includes a substrate, a semiconductor chip mounted on the substrate, a molding portion surrounding a side of the semiconductor chip on the substrate, and an embedded portion of the molding portion. and a heat-conducting member that radiates heat generated from the semiconductor chip to the outside of the molding part.

Here, a concave portion with a predetermined thickness is formed on at least one side of the molding portion, and the heat-conducting member includes a heat-conducting sheet bonded to the inside of the concave portion to radiate heat generated from the semiconductor chip to the outside. .

A concave-convex surface with a plurality of irregularities is formed on the bottom surface of the concave portion, and the heat-conducting member further includes a metal layer deposited on the concavo-convex surface and a solder paste applied on the metal layer, so that the heat-conducting sheet is attached to the metal layer. It is joined by soldering.

In addition, a heat dissipation semiconductor package manufacturing method according to the present invention for solving the above problems includes providing a semiconductor package for which the packaging process of a conductor chip has been completed; forming an engraved portion with a concavo-convex surface through laser processing on at least one side of the molding portion forming the outer shape of the semiconductor package; depositing a metal layer on the uneven surface through plating; dispensing solder paste on the metal layer; Mounting a heat-conducting sheet on the solder paste; and melting the solder paste by heating the solder paste.

Meanwhile, it is an induction heating soldering device that inductively heats the metal layer deposited on the surface of the molding part of the heat dissipation semiconductor package according to the present invention and solders a heat-conducting sheet to the metal layer, and is electrically connected to a high-frequency power supply unit to induce electromagnetism. coil; a magnetic core located inside the induction heating coil to focus magnetic flux onto the heat-conducting sheet; and a coil bobbin in which the induction heating coil is disposed on an outer surface and the magnetic core is installed in the center, wherein the coil bobbin is open at the top so that cooling air flows into the coil bobbin through the upper opening, A plurality of through holes are formed on the side of the coil bobbin so that the cooling air can be discharged to the outside through the through holes after passing through the magnetic core.

The heat-dissipating semiconductor package with an embedded heat-conducting member of the present invention configured as described above and its manufacturing method have the following advantages.

First, because the heat conduction member that dissipates heat generated inside the semiconductor package to the outside is embedded within the thickness of the molding part that forms the exterior of the semiconductor package, optimal heat conduction can be achieved within the minimum thickness of the molding part of the semiconductor package. There are benefits to this.

Second, heat within the semiconductor package can be efficiently discharged without the need for an external heat dissipation member, which has the advantage of realizing high capacity, miniaturization, and high reliability.

Third, as the heat conduction member is embedded in the surface of the molding part, heat conduction members can be installed on the top and/or sides of the molding part, thereby realizing three-dimensional heat dissipation and heat conduction. Additionally, depending on the spatial environment in which the semiconductor package is installed, the heat dissipation area can be There is an advantage in being able to respond actively.

Fourth, by directly implementing the heat-conducting member in the semiconductor package that has completed the semiconductor packaging process, layout design is possible in a continuous process (in-line process) after the packaging process, which is very advantageous for mass production.

Fifth, the heat conduction member is implemented as a porous engraving (concavo-convex surface) on the surface of the molding part, which has the advantage of greatly expanding the heat dissipation surface area and allowing a large amount of heat to be quickly discharged.

Sixth, it is possible to universally respond to various semiconductor package implementation methods such as wire bonding, film chip bond, and TSV (Through Silicon Via), and also has the advantage of improving heat dissipation performance in fan-out wafer level packages, which will be the main package type in the future. .

Figure 1 is a photograph taken of a state in which a conventional TIM sheet is attached to a semiconductor package.
Figure 2 is a schematic cross-sectional view of a heat dissipation semiconductor package according to an embodiment of the present invention.
Figure 3 is a photograph of an actual product in which a heat-conducting member is directly implemented in a heat dissipation semiconductor package according to an embodiment of the present invention.
Figure 4 is a diagram showing an example of a use state of a heat dissipation semiconductor package according to an embodiment of the present invention.
Figure 5 is a flow chart showing the process sequence for manufacturing a heat dissipation semiconductor package according to an embodiment of the present invention.
6A to 6C are conceptual diagrams showing the process sequence for manufacturing a heat dissipation semiconductor package according to an embodiment of the present invention.
Figure 7 is a diagram showing the process sequence for manufacturing a heat dissipation semiconductor package according to an embodiment of the present invention as an actual product.
Figure 8 is a conceptual diagram showing that the eight processes for manufacturing a conventional semiconductor package and the process for manufacturing a heat dissipation semiconductor package according to an embodiment of the present invention are implemented as a continuous in-line process.
Figure 9 is a conceptual diagram showing a side cooling air discharge type from an induction heating unit applied to a heat dissipation semiconductor package according to an embodiment of the present invention.
Figure 10 is a conceptual diagram showing the upper cooling air discharge type from the induction heating unit applied to the heat dissipation semiconductor package according to an embodiment of the present invention.

Since the present invention can be modified in various ways and can have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all transformations, equivalents, and substitutes included in the spirit and technical scope of the present invention. In describing the present invention, if it is determined that a detailed description of related known technologies may obscure the gist of the present invention, the detailed description will be omitted.

The core technical idea of the present invention is to implement a heat dissipation means (hereinafter referred to as a heat conduction member) that radiates heat generated inside the semiconductor package to the outside by embedding it in a molding part forming the outer shape of the semiconductor package. It has the advantage of realizing optimal heat conduction within the minimum thickness of the molding part.

For this purpose, the present invention forms a concave concave part with a certain thickness in the molding part of the hot spot ('A' in FIG. 4) of the semiconductor package, deposits a metal layer on this engraved part, and then deposits a metal layer on the engraved part. , It is joined to a metal layer with a heat-conducting sheet through a soldering process.

Hereinafter, an embodiment of a heat dissipation semiconductor package with an embedded heat conduction member according to the present invention will be described in detail with reference to the attached drawings.

Figure 2 is a schematic cross-sectional view of a heat dissipation semiconductor package according to an embodiment of the present invention, and Figure 3 is a photograph of an actual product in which a heat conduction member is directly implemented in a heat dissipation semiconductor package according to an embodiment of the present invention. Figure 4 is a diagram showing an example of a use state of a semiconductor package according to an embodiment of the present invention.

Referring to Figures 2 and 3, the heat dissipation semiconductor package in which the heat conduction member is embedded according to the present invention includes a substrate 10, a semiconductor chip 20, a molding part 30, a heat conduction member 40, and a solder ball 50. It consists of, etc.

As the substrate 10, for example, a printed circuit board (PCB board) is used. One or two or more semiconductor chips are mounted on one surface of the substrate 10. On the other hand, the other side of the board 10 (the side opposite to the one side) has a connection structure that can be connected to another PCB board (for example, motherboard: 80 in FIG. 4). Examples of the connection structure include solder balls 50 and pin connectors.

However, the present invention is not limited to the substrate type. That is, the lead frame type can be applied instead of the substrate type. In other words, in terms of the electrical connection method of the semiconductor chip, it is possible to connect it by attaching a solder ball to the board, and it may also be possible to connect it to a lead frame using a wire.

The semiconductor chip 20 may be a semiconductor chip that performs various functions such as memory, logic, microprocessor, analog element, digital signal processor, and system on chip. Additionally, the semiconductor chip may be a multi-chip having a structure in which at least two or more semiconductor chips are stacked. For example, at least two semiconductor chips may all be the same type of device, or one of the two or more semiconductor chips may be a memory device and the other may be a microcontroller device.

The semiconductor chip 20 shown in FIG. 2 is mounted on the substrate 10 using a flip-chip bonding method, but the mounting method of the semiconductor chip 20 is not limited to this. For example, semiconductor chips may be mounted on a substrate using a wire bonding method, or they may be mounted using a TSV (Through Silicon Via) method in which multiple semiconductor chips are stacked and connected to each other through via holes. there is.

As shown in FIG. 2 , when the semiconductor chip 20 is mounted using a flip-chip bonding method, the semiconductor chip 20 may be connected to the substrate 10 through the bump 60 . Meanwhile, configuration number ‘70’, which is not explained in FIG. 2, is a protective film to protect the semiconductor chip. At this time, the protective film 70 has the form of an oxide film, a nitride film, or a film.

The molding part 30 serves to seal the semiconductor chip 20 and protect the semiconductor chip 20 from hazardous elements in the external environment. This molding portion 30 is made of an insulating material, for example, a thermosetting resin such as an epoxy resin, a thermoplastic resin such as polyimide, or a resin containing reinforcing materials such as an inorganic filler, specifically, ABF, FR-4, and BT resin. It may include etc. Additionally, a molding material such as EMC (Epoxy molding compound) may be used for the molding portion 30. Here, EMC is a thermosetting plastic that is a resin with a relatively low molecular weight that can be three-dimensionally cured in the presence of a curing agent or catalyst and has excellent mechanical, electrical insulation, and temperature resistance properties. Of course, in the present invention, the material of the molding part 30 is not limited to the materials described above.

In this way, the molding part 30 performs roles such as mechanical protection, electrical connection, and mechanical connection of the semiconductor chip 20. However, recently, as semiconductor technology has advanced, product speeds have increased, and functions have increased, heat problems have become very serious, and technologies that effectively dissipate heat from the molding part 30 are being applied. That is, the molding part 30 protects the semiconductor chip 20 from external mechanical and chemical shock by covering it with a packaging material such as EMC resin, and physically/electrically connects the semiconductor chip 20 to the system to form the semiconductor chip 20. It supplies power for this operation, allows input and output of signals to perform desired functions, and also serves to radiate heat generated when the semiconductor chip 20 operates.

In view of the above, the present invention implements a heat conduction member (40: heat dissipation means) in the molding portion (30) that dissipates heat generated in the semiconductor chip (20) to the outside of the semiconductor package. That is, the heat-conducting member 40 is implemented within the thickness of the molding portion 30. In the present invention, it is defined and used as a heat-conducting member embedded in the molding part 30.

Hereinafter, the heat conduction member 40 embedded in the molding part 30 will be described in more detail with reference to FIGS. 2 to 4 and 6A to 6B.

The heat-conducting member 40 includes a metal layer 41 formed on the molding part 30 and a heat-conducting sheet 42 bonded to the metal layer 41. For this purpose, an engraved portion 31 on which the metal layer 41 is deposited is formed on one surface of the molding portion 40, and an uneven surface 42 formed on the bottom surface of the engraved portion 31.

The engraved portion 31 may be formed to have a certain depth in at least one area of the first surface of the molding portion. This engraved portion 31 can be formed by removing the molding portion 30 to a certain depth through laser processing, etc., which will be described later. For example, as shown in FIG. 6A, in order to protect the semiconductor chip 20 at the initial thickness of the molding portion 30, only the molding portion with a thickness of 5 to 10 μm is left on the semiconductor chip 20 and the remaining portion is removed. A concave portion 31 can be formed. However, it is not limited to this, and the depth of the engraved portion 31 may vary depending on the type and size of the semiconductor package or semiconductor chip.

At this time, the engraved portion 31 has the shape of a concave groove with a four-angled plane inside, with an edge of a certain width on one side of the molding portion 30, as shown in FIG. 3(a). It may also have the shape of a concave groove extending radially from the center and vertex of each side in a four-sided plane to the edge of the molding portion 30, as shown in FIG. 3(b). In the latter case, the area of the heat-conducting member 40 can be maximized, which has the advantage of having a better heat dissipation effect.

As shown in FIGS. 6A and 6B, the convex and convex surface 32 periodically repeats convex and concave patterns on the bottom surface of the engraved part 31 when forming the engraved part 31 through laser processing, etc. It may have a diagonal or straight concave-convex shape. However, the present invention is not limited to this and may have many different shapes. This uneven surface 32 can increase the bonding force with the metal layer 41 through anchoring of metal materials in the deposition process for forming the metal layer 41, and the heat dissipation surface area can be expanded to increase the heat dissipation effect. do.

As shown in FIG. 6B, the metal layer 41 is formed on the concavo-convex surface 32 inside the concave portion 31 and plays a role in vertically transmitting heat generated from the semiconductor chip 20. In addition, it serves as a medium for soldering the heat-conducting sheet 42 to the molding part 30 made of resin material. This metal layer 41 has a structure in which the metal layer 41 is plated and deposited on the engraved area. To elaborate further, the metal layer 41 is formed inside the engraved portion 31 by a selective plating process, and can be performed by dry or wet plating depending on laser processing and the state of the semiconductor package. A more detailed description of the process for forming the metal layer 41 will be described later.

Here, the metal layer 41 may be composed of multiple layers. According to various embodiments, the metal layer may include a first metal layer 41a and a second metal layer 41b. Here, the first metal layer 41a is formed directly on the laser-processed engraved part 31, and serves to provide high bonding strength through anchoring to the molding part 30 made of a resin material and to form a bond between the semiconductor chip 20 and the semiconductor chip 20. Since there may be contact areas, it is advisable to use a metal material with low diffusivity. For example, the first metal layer 41a may include at least one of copper (Cu), nickel (Ni), aluminum (Al), titanium (Ti), and silicon (Si). And the second metal layer 41b has excellent solderability for solder bonding with the heat conductive sheet 420 and acts as a heat conduction intermediate layer after bonding. Therefore, the second metal layer 41b is made of a metal material with excellent soldering and good heat conduction. For example, the second metal layer 41b may include at least one of copper (Cu), nickel (Ni), and gold (Au).

The heat conductive sheet 42 is bonded to the metal layer 41 in the form of a thin plate made of a heat conductive material. More specifically, it is bonded to the second metal layer 41b. This heat-conducting sheet 42 is disposed on the outermost side of the engraved portion 31 of the molding portion 30 and serves to radiate heat generated from the semiconductor chip 20 to the outside of the semiconductor package.

In addition, as shown in FIG. 4, when the heat dissipation semiconductor package of the present invention is assembled on the motherboard 70 of an electronic device, it is connected to the TIM sheet 300 and/or the EMI shielding member 400, which are additional heat dissipation means, to provide external heat dissipation. can effectively dissipate heat. Here, the TIM sheet 300 includes a sheet made of a thermally conductive interface material (TIM), and the EMI shielding member 400 is installed around the semiconductor package to block electromagnetic waves.

The heat-conducting sheet 42 may be made of a metal material such as copper or aluminum, a metalloid material such as silicon, or a carbon-based fiber such as carbon or graphite. Of course, in the present invention, the material of the heat-conducting sheet is not limited to the materials described above.

Referring to FIGS. 6B and 6C, the heat-conducting sheet 42 may be bonded to the metal layer 41 through soldering. For this purpose, solder paste 43 is applied between the heat-conducting sheet 42 and the metal layer 41.

Here, two major methods can be considered for soldering the heat-conducting sheet 42 to the metal layer 41. One of the soldering methods is the reflow soldering method, and the other is the induction heating soldering method.

However, when soldering using the reflow soldering method, a material with high heat resistance must be used because the molding part must withstand high temperatures, and thermal damage may be caused to semiconductor chips included in the semiconductor package during the soldering process. Therefore, in the present invention, it is more preferable to solder the heat-conducting sheet using an induction heating method rather than a reflow soldering method.

On the other hand, induction heating soldering only locally heats the conductor located inside the magnetic field formed by the induction heating coil, so there is no need to use a material with high heat resistance as the molding part, and in particular, it does not cause thermal damage to the semiconductor chip contained in the semiconductor package. There is an advantage to not having any at all. The method of joining the metal layer of the heat conduction sheet through induction heating soldering will be described in more detail later.

With the above-described configuration, the heat dissipation semiconductor package according to the present invention allows heat generated from the semiconductor chip to be transferred directly to the metal layer and the heat-conducting sheet through the concave part forming the minimum thickness in the molding part and released into the air, and can also be released to the outside. It may also be emitted to the outside through other heat dissipation members (TIM sheets or EMI shielding members).

As previously described, in the heat dissipation semiconductor package of the present invention, metallization (metal layer) is formed on a molding part that forms the exterior of the semiconductor package (MID: Mold Interconnected Device), and a heat-conducting sheet is bonded to the metal layer by soldering. Accordingly, the heat-conducting member can be mounted directly while embedded inside a molding part made of plastic (MDM: Molding Direct Mounting).

In this way, the heat dissipation semiconductor package according to the present invention can directly form a heat conduction member by applying MID and MDM to the plastic molding part forming the outer shape, thereby enabling three-dimensional heat dissipation and heat conduction according to the three-dimensional shape of the semiconductor package. can be implemented, and this has the advantage of being able to actively respond to the heat dissipation area according to the spatial environment in which the semiconductor package is installed.

Hereinafter, a method of manufacturing a heat dissipation semiconductor package with an embedded heat-conducting member according to an embodiment of the present invention will be described with reference to FIGS. 5 to 7.

Figure 5 is a flow chart showing the process sequence for manufacturing a heat dissipation semiconductor package according to an embodiment of the present invention, and Figures 6A to 6C present a conceptual diagram showing the process sequence for manufacturing a heat dissipation semiconductor package according to an embodiment of the present invention. 7 shows the process sequence for manufacturing a heat dissipation semiconductor package according to an embodiment of the present invention as an actual product.

First, a semiconductor package for which the semiconductor packaging process has been completed is provided (step S10 in FIG. 5, FIG. 6a), and a certain area is removed by laser processing on the upper surface of the molding part 30 forming the outline of the semiconductor packaging to form an engraved portion ( 31) (step S20 in Figure 5, Figure 6a, Figure 7(a)). At this time, as the engraved portion 31 is formed through laser processing, a pattern groove in the form of fine unevenness is formed on the bottom surface of the engraved portion 31. That is, an uneven surface 32 in the form of a diagonal or straight line in which convex and concave patterns are periodically repeated may be formed on the bottom surface of the intaglio portion 31. The laser may be a diode laser, UV (ultraviolet) laser, excimer laser, etc. In the present invention, forming an engraved portion is not limited to laser processing, and various methods such as CNC (computerized numerical control) milling, wet etching, and dry etching can be applied.

Afterwards, a metal layer 41 is deposited by plating metal in the area of the concave portion 31 (S30 in Fig. 5, Fig. 6b, Fig. 7(b)). Here, the metal layer 41 is made of at least one of copper (Cu), nickel (Ni), aluminum (Al), titanium (Ti), and silicon (Si) on the uneven surface 32 forming the bottom surface of the intaglio portion 31. It may be formed by stacking a first metal layer 41a containing one and a second metal layer 41b containing at least one of copper (Cu), nickel (Ni), and gold (Au) on the first metal layer. . This metal layer 30 is selectively coated with metal in the area of the concave portion using dry thin film deposition methods such as wet plating using masking (100 in FIG. 6b), CVD (Physical Vapor Deposition), PVD (Chemical Vapor Deposition), and E-BEAM. Anger can be realized

Next, the heat conductive sheet 42 is soldered on the metal layer 30 by induction heating and placed directly on the molding part. For this purpose, solder paste 43 is dispensed on the metal layer 41 (S40 in Fig. 5, Fig. 6b, Fig. 7(c)). Then, the heat-conducting sheet 42 is mounted on the solder paste 43 (S50 in FIG. 5, FIG. 6c). Thereafter, the induction heating unit 200 is placed on the heat-conducting sheet 42 and heated induction (S60 in FIGS. 5 and 6C), thereby melting the solder paste 43 to form the heat-conducting sheet 42 into a molding portion ( 30) can be embedded in the thickness (S70 and 7(d) of Figure 5).

At this time, the induction heating unit 200 inductively heats the metal layer 41. As a result, the solder paste 43 applied between the molding part 30 and the heat-conducting sheet 42 melts, and the heat-conducting sheet 42 can be directly mounted on the concave part 31 of the molding part 30 made of plastic. You can.

Here, the induction heating unit 200 includes an induction heating coil 210 electrically connected to a high-frequency power supply unit (not shown), and is disposed inside the induction heating coil 210 and induced by the induction heating coil 210. It consists of a magnetic core 220 to focus the magnetic flux to the soldering area. At this time, the induction heating unit 200 is not shown, but can be moved in the X-axis/Y-axis/Z-axis directions through a transfer robot (not shown) to continuously solder electronic elements mounted on multiple circuit bricks. You can. Additionally, the transfer robot (not shown) is equipped with a plurality of induction heating units and can simultaneously solder a plurality of semiconductor packages at once.

As described above, a heat-conducting sheet can be directly embedded in a molding part made of plastic injection using magnetic induction local heating of the metal layer. Because of this, compared to the general reflow soldering method, it can be used without restrictions on the material of the molding part that forms the exterior of the semiconductor package, and a heat-conducting sheet can be implemented in the molding part without thermal damage to components such as semiconductor chips mounted inside. It becomes possible.

Meanwhile, as shown in FIG. 8, the heat dissipation semiconductor package according to the present invention implements a heat conduction member directly in the molding part formed through the semiconductor packaging process, so that it can be manufactured further in-line after the eight manufacturing processes of the existing semiconductor package. This is very advantageous for mass production and production line construction.

In addition, a cooling structure that can cool the heat of the magnetic core 220 is applied to the induction heating unit 200 used when manufacturing the heat dissipation semiconductor package of the present invention, providing an induction heating unit that can improve soldering quality. .

Figure 9 is a conceptual diagram showing a side cooling air discharge type from an induction heating unit applied to a heat dissipation semiconductor package according to an embodiment of the present invention.

Referring to FIG. 9, the induction heating unit 200 includes an induction heating coil 210, a magnetic core 220, and a coil bobbin 230.

The induction heating coil 210 is electrically connected to a high-frequency power supply unit (not shown) to induce electromagnetism, and uses a hollow copper tube with high electrical conductivity. The induction heating coil 210 has a cooling water passage formed inside the hollow space to supply cooling water 235. Accordingly, the heat generated in the magnetic core 220 can be quickly dissipated toward the induction heating coil 210. Here, the overall shape of the induction heating coil 210 can be implemented in various shapes such as helical, square, and circular. Furthermore, depending on the type of semiconductor package and the soldering environment, it may be in the form of a very thin wire (for example, Litz wire) rather than a hollow tube.

The magnetic core 220 is located inside the induction heating coil 210 and serves to concentrate the magnetic induction generated by the induction heating coil 210. Here, the magnetic core 220 can be configured in various shapes such as round, square, or hollow.

The coil bobbin 230 serves as a housing in which a magnetic core 220 is inserted inside and an induction heating coil 210 is placed outside. At this time, the coil bobbin 230 also serves as a pressing plate to prevent the heat-conducting sheet 32 from lifting during soldering.

A spiral groove may be formed on the outer surface of the coil bobbin 230 so that the induction heating coil 210 can be stably fixed in place. And on the side of the coil bobbin 230, a plurality of through holes 231 that serve as passages for cooling air are formed at regular intervals up and down. At this time, the inner surface of the coil bobbin 230 where the through hole 231 is formed has a relatively wide diameter flow so that the cooling air flowing in from the upper part of the coil bobbin 230 can flow smoothly into the through hole 231. It is desirable for the hole 234 to be formed.

Meanwhile, the upper part of the coil bobbin 230 has an open structure to allow cooling air to flow in. Accordingly, the cooling air flowing into the upper part of the coil bobbin 230 passes through the magnetic core 220 and exits through the through hole 231, thereby quickly discharging the heat generated in the magnetic core 220 to the outside. . At this time, for effective heat exchange with cooling air, the magnetic core 220 is either a hollow shape with its interior open at the top and bottom, or a shape that allows a hollow internal space to be maintained inside the coil bobbin 230. desirable.

In this way, the induction heating unit 200 applied to the present invention cools the magnetic core 220 using cooling air, so that the magnetic core 220 is not heated to a high temperature, thereby effectively focusing the magnetic flux of the induction heating coil 210. This has the effect of greatly improving the soldering quality of heat-conducting members within a semiconductor package.

Meanwhile, Figure 10, unlike Figure 9, applies the top cooling air discharge type as the cooling structure of the induction heating unit.

That is, an entirely closed structure is applied rather than a through-hole 231 formed on the side of the coil bobbin 230, and a partition wall 232 is formed in the center of the open upper part of the coil bobbin 230. At this time, cooling air is injected to one side around the partition wall 232, and air that has completed heat exchange with the magnetic core 220 is discharged to the other side. To be more specific, the air flowing in to one side around the partition wall 232 passes through the magnetic core 220 inserted inside the coil bobbin 230, and then passes through the magnetic core 220 inserted into the coil bobbin 230, and then flows into the air flowing in to the other side around the partition wall 232. There is a flow that radiates heat generated in the magnetic core 220 to the outside as it exits through the opening. At this time, on the inner surface of the bobbin coil 230 in contact with the magnetic core 220, a plurality of flow grooves 234 in the form of grooves recessed inward are formed at regular intervals up and down. Accordingly, sufficient heat exchange with cooling air occurs not only inside the magnetic core 220 but also outside the magnetic core 220, so that the cooling efficiency of the magnetic core 220 can be improved.

Although each embodiment of the present invention has been described above with reference to the drawings, those skilled in the art will understand the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. You will understand that it can be modified and changed in various ways.

And, the semiconductor package according to the present invention can be widely used in many industrial fields for all kinds of purposes such as smartphones, tablets, wearables, digital cameras, wireless routers, etc.

10: substrate 20: semiconductor chip
30: molding part 31: concave part
32: uneven surface 40: heat conduction member
41: metal layer 42: heat conduction sheet
41a: first metal layer 41b: second metal layer
43: solder paste 50: solder ball
60: Bump 70: Shield
80: motherboard
200: induction heating unit 210: induction heating coil
220: magnetic core 230: coil bobbin
231: Through hole 232: Partition wall
233: flow hole 234: flow groove
235: Coolant

Claims (11)

Board;
a semiconductor chip mounted on the substrate;
a molding portion surrounding a side of the semiconductor chip on the substrate; and
A heat-conducting member formed in the molding portion to radiate heat generated from the semiconductor chip to the outside of the molding portion. In claim 1,
The heat conducting member is,
A metal layer deposited on at least one side of the molding part;
Solder paste applied on the metal layer; and
A heat-conducting sheet soldered to the metal layer using the solder paste. Board;
a semiconductor chip mounted on the substrate;
a molding portion surrounding a side of the semiconductor chip on the substrate; and
A heat-conducting member embedded in the molding portion to radiate heat generated from the semiconductor chip to the outside of the molding portion. In claim 3,
A concave concave portion with a certain thickness is formed on at least one side of the molding part,
The heat-conducting member is a heat-dissipating semiconductor package with an embedded heat-conducting member, characterized in that it includes a heat-conducting sheet bonded to the inside of the concave portion to radiate heat generated from the semiconductor chip to the outside. In claim 4,
An uneven surface with a plurality of irregularities is formed on the bottom surface of the intaglio part,
The heat-conducting member further includes a metal layer deposited on the uneven surface and a solder paste applied on the metal layer, and the heat-conducting sheet is bonded to the metal layer by soldering. In claim 2 or claim 5,
The metal layer is.
A first metal layer formed on the uneven surface and including at least one of copper (Cu), nickel (Ni), aluminum (Al), titanium (Ti), and silicon (Si); and
a second metal layer formed on the first metal layer and including at least one of copper (Cu), nickel (Ni), and gold (Au); A heat dissipation semiconductor package with an embedded heat conduction member, comprising: In claim 1 or claim 3,
A heat-dissipating semiconductor package with an embedded heat-conducting member, wherein the heat-conducting sheet is made of a material with higher thermal conductivity than the material forming the molding part. In claim 7,
A heat dissipation semiconductor package with an embedded heat conduction member, wherein the heat conduction sheet is made of metal, carbon fiber, graphite, or ceramic. Providing a semiconductor package for which the semiconductor chip packaging process has been completed;
forming an engraved portion with a concavo-convex surface through laser processing on at least one side of the molding portion forming the outer shape of the semiconductor package;
depositing a metal layer on the uneven surface through plating;
dispensing solder paste on the metal layer;
Mounting a heat-conducting sheet on the solder paste; and
A method of manufacturing a heat-dissipating semiconductor package with an embedded heat-conducting member, comprising the step of melting the solder paste by heating the solder paste. In claim 9,
The heating method for melting the solder paste uses induction heating soldering,
disposing an induction heating unit adjacent to the heat-conducting sheet; and
A method of manufacturing a heat dissipation semiconductor package with an embedded heat conduction member, comprising the step of melting the solder paste by the induction heating unit so that the heat conduction sheet is substantially directly mounted within the molding part.
An induction heating soldering device for inductively heating a metal layer deposited on the surface of a molding part of a semiconductor package and soldering a heat-conducting sheet to the metal layer,
An induction heating coil 210 that is electrically connected to a high-frequency power supply unit to induce electromagnetism;
A magnetic core 220 located inside the induction heating coil 210 to concentrate magnetic flux onto the heat-conducting sheet; and
A coil bobbin 230 in which the induction heating coil 210 is disposed on the outer side and the magnetic core 220 is installed in the center,
The coil bobbin 230 is open at the top so that cooling air flows into the coil bobbin through the top opening, and a plurality of through-holes 231 are formed on the side of the coil bobbin 230 to allow the cooling air. An induction heating soldering device, characterized in that after passing through the magnetic core (220), it is discharged to the outside through the through hole (231).

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