JP3946659B2 - High heat dissipation plastic package and manufacturing method thereof - Google Patents

Description

[0001]
[Technical field to which the invention belongs]
The present invention relates to a high heat dissipation plastic package for mounting a semiconductor element and a manufacturing method thereof, and more particularly to a high heat dissipation plastic package formed by bonding a resin substrate and a heat dissipation plate and a manufacturing method thereof.
[0002]
[Prior art]
With recent high performance and miniaturization of semiconductor devices, plastic packages for mounting semiconductor devices have increased the amount of heat generated from the semiconductor devices, increased the number of terminals for external connection, and mounting of semiconductor devices From the viewpoints of performance, cost reduction, impedance reduction, and the like, high heat dissipation plastic packages such as BGA (Ball Grid Array) type having a high heat dissipation structure are often used. This high heat dissipation type plastic package has a single layer or multiple layers made of BT resin (resin mainly composed of bis-maleimide triazine) or polyimide resin provided with a conductor layer formed by bonding Cu foil on one side or both sides. A heat radiating plate made of a metal plate such as Cu having a high thermal conductivity is joined to a high heat resistant resin substrate via an adhesive such as a prepreg (for example, see Patent Document 1 and Patent Document 2).
[0003]
With reference to FIGS. 7A to 7D, a conventional method of manufacturing a high heat dissipation plastic package 50 will be described. As shown in FIG. 7 (A), a through hole 53a for a through hole 53 is formed in a resin substrate 51 containing a glass cloth to which a Cu foil 52 is bonded in order to conduct the front and back surfaces. Further, an electroless Cu plating film is provided on the front surface, the back surface, and the wall surface of the through-hole 53a, and the Cu plating film 54 is formed by energizing the electroless Cu plating film to provide the electrolytic Cu plating film. Next, as shown in FIG. 7B, a dry film is stuck on the Cu plating film 54, an etching resist pattern is formed by a photolithography method in which a pattern mask is brought into contact, exposed and developed, and an etching resist is formed. The Cu plating film 54 and the Cu foil 52 exposed from the opening of the pattern are removed by etching, and the dry film is peeled and removed to form the wiring pattern 55. Next, as shown in FIG. 7C, in order to form a cavity part for mounting a semiconductor element on the resin substrate 51 on which the wiring pattern 55 is formed, it is substantially viewed in plan using a router processing machine. A notch 56 having a rectangular shape is formed. Next, as shown in FIG. 7D, a heat dissipation plate 57 made of a resin substrate 51 and a Cu plate or the like is bonded by thermocompression bonding via an adhesive 58 such as a prepreg, thereby producing a high heat dissipation type plastic package 50. is doing. Note that a solder resist film 59 is usually formed on the upper surface side of the resin substrate 51 so that a necessary portion of the wiring pattern 55 is exposed from the opening.
[0004]
As a BGA type package with good heat dissipation, a package has been proposed in which a TAB (Tape Automated Bonding) tape is joined to a reinforcing plate with good heat dissipation with a thermosetting adhesive (for example, see Patent Document 3). .
[0005]
[Patent Document 1]
Japanese Patent Laid-Open No. 7-321250 (page 1-14, FIG. 1)
[Patent Document 2]
Japanese Patent Laid-Open No. 10-308467 (page 1-5, FIG. 2)
[Patent Document 3]
Japanese Unexamined Patent Publication No. 2001-68512 (page 1-6, FIG. 1)
[0006]
[Problems to be solved by the invention]
However, the conventional high heat dissipation plastic package and the manufacturing method thereof as described above have the following problems.
(1) Since the base material for forming a conductor wiring pattern and the heat radiating plate are joined by using an adhesive to be attached later, the overall thickness after joining is increased by the thickness of the adhesive part, For example, it is hindering use in electronic devices such as mobile phones and personal computers that are required to be light and thin.
(2) When a retrofitting adhesive is used to join the conductor wiring pattern forming substrate and the heat sink, the adhesive is applied to the resin substrate or the heat sink with high accuracy, or the adhesive sheet is accurately applied. Adhering requires time, man-hours, and material costs, which increases the cost of the high heat dissipation plastic package. In addition, when bonding is performed using an adhesive or an adhesive sheet, bleeding of the bonding resin into the cavity portion occurs at the time of bonding, resulting in a decrease in reliability when the semiconductor element is mounted in the cavity portion. Yes.
The present invention has been made in view of such circumstances, and without using a thick adhesive material such as a prepreg between the resin substrate and the heat radiating plate, there is little resin oozing out of the adhesive material, and it is inexpensive. An object of the present invention is to provide a high heat radiation type plastic package with good joining accuracy and a small thickness, and a method for manufacturing the same.
[0007]
[Means for Solving the Problems]
The high heat radiation type plastic package according to the present invention, which meets the above-mentioned object, is formed by bonding an adhesive resin to a Cu foil, and is a cut for a cavity portion for placing a semiconductor element in a substantially central portion in plan view. A resin film with a Cu foil having a notch and a heat radiating plate for radiating heat generated from a semiconductor element are directly bonded with an adhesive resin, and the heat radiating plate includes Cu It has a restraining part for preventing the resin oozing out at the time of joining of the resin for adhesion of the resin film with foil. This eliminates the use of a post-adhesive adhesive such as a prepreg for joining the heat-radiating plate to the resin film with Cu foil, which is a substrate for forming a conductor wiring pattern. It is possible to provide a high heat radiation type plastic package with good bonding accuracy between the resin film and the heat sink. In addition, since it is possible to prevent the resin from bleeding into the cavity during bonding of the adhesive resin, it is possible to provide a high heat radiation type plastic package capable of improving the mounting reliability of the semiconductor element.
[0008]
Here, it is preferable that the high heat radiation type plastic package has a step where the stop portion can be mounted with a slight clearance in the notch. As a result, it is possible to prevent the resin from bleeding into the cavity portion of the adhesive resin at the step portion that can be formed so that the cavity portion protrudes in a convex shape, so that high heat radiation type plastic that can improve the mounting reliability of the semiconductor element Package can be provided.
[0009]
In addition, the high heat dissipation plastic package may include a groove in which the stop portion is formed along the periphery of the notch. Thereby, since the resin portion can be prevented from leaking into the cavity portion of the adhesive resin at the groove portion, it is possible to provide a high heat radiation type plastic package capable of improving the mounting reliability of the semiconductor element.
[0010]
The manufacturing method of the high heat radiation type plastic package according to the present invention, which meets the above-mentioned object, is a method for cutting a cavity part for bonding a resin for bonding to a Cu foil and placing a semiconductor element in a substantially central part in plan view. A method of manufacturing a high heat radiation type plastic package in which a resin film with Cu foil formed by drilling a notch and a heat sink for radiating heat generated from a semiconductor element are directly joined with an adhesive resin. , A step of forming a step or groove along the periphery of the notch of the Cu foil resin film on the heat sink, and heating the adhesive resin to bond the Cu foil resin film and the heat sink, A step of stopping the resin oozing of the resin with a step or a groove. Accordingly, it is possible to provide a method for manufacturing an inexpensive high heat radiation type plastic package that can be bonded to the heat sink easily and accurately at once with the adhesive resin for the resin film with Cu foil and that is thin. In addition, the occurrence of resin oozing out of the adhesive resin on the heat sink of the cavity can be prevented by the step or groove, so that the semiconductor element can be mounted with high bonding reliability, and the heat generated from the semiconductor element can be radiated efficiently. It is possible to provide a method for manufacturing a high heat dissipation plastic package.
[0011]
According to another aspect of the present invention, there is provided a method for manufacturing a high heat dissipation plastic package according to the present invention, wherein a bonding resin is bonded to a Cu foil and a semiconductor element is placed in a substantially central portion in plan view. Manufacturing of high heat dissipation plastic packages in which a resin film with a Cu foil formed by drilling a notch for a part and a heat sink for radiating heat generated from a semiconductor element are directly joined with an adhesive resin A method of pressing a release film via a low-melting point resin film onto a cavity part and a resin film with Cu foil using a pressing jig having a convex part that can be fitted into a notch of the resin film with Cu foil; The adhesive resin is heated to bond the resin film with the Cu foil and the heat sink, and the resin oozing of the adhesive resin is controlled by the release film via the low melting point resin film. A step of, to remove the pressing jig, comprising the step of removing the release film through a low-melting point resin film. Accordingly, it is possible to provide a method for manufacturing an inexpensive high heat radiation type plastic package that can be bonded to the heat sink easily and accurately at once with the adhesive resin for the resin film with Cu foil and that is thin. In addition, it is possible to prevent the occurrence of resin seepage of the adhesive resin on the heat sink of the cavity with a release film through a low melting point resin film pressed by a holding jig, thereby increasing the bonding reliability of the semiconductor element. It is possible to provide a manufacturing method of a high heat radiation type plastic package that can be mounted and can efficiently dissipate heat generated from a semiconductor element.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described with reference to the accompanying drawings to provide an understanding of the present invention.
1A and 1B are a perspective view and a longitudinal sectional view of a high heat dissipation plastic package according to an embodiment of the present invention, respectively, and FIGS. 2A to 2C are the same modification examples. 3A and FIG. 3B are a heat radiating plate of the high heat radiating plastic package and a modified high heat radiating plastic package, respectively. 4A to 4E are explanatory diagrams of the manufacturing method of the high heat dissipation plastic package, and FIGS. 5A to 5E are high heat dissipation plastics of the same modification. FIGS. 6A to 6D are explanatory views of another manufacturing method of the high heat dissipation plastic package and the modified high heat dissipation plastic package, respectively.
[0013]
As shown in FIGS. 1A and 1B, a high heat dissipation plastic package 10 according to an embodiment of the present invention includes a resin film 11 with Cu foil and a heat dissipation plate 12. The resin film 11 with Cu foil is formed into a film by applying an adhesive resin 13 that does not include a glass cloth base material to a Cu foil. The resin film 11 with Cu foil is provided with a notch 15 for a cavity portion 14 for mounting a semiconductor element in a substantially central portion of the package in a plan view by punching with a punching press or the like. On the other hand, the heat radiating plate 12 is made of a Cu plate or the like having a high thermal conductivity so that heat generated from the semiconductor element can be efficiently radiated, and the surface is roughened to improve the bonding strength with the adhesive resin 13. Has been applied. Further, the heat radiating plate 12 is provided with a restraining portion for preventing resin oozing that occurs in the cavity portion 14 when bonded to the adhesive resin 13 formed by bonding to the resin film 11 with Cu foil. ing. Then, the resin film 11 with Cu foil and the heat radiating plate 12 are brought into contact with the thermosetting adhesive resin 13 and the heat radiating plate 12 constituting the resin film 11 with Cu foil, and are heated and pressed to apply the adhesive resin 13. It is joined while curing.
[0014]
This high heat dissipation plastic package 10 is provided with a conductor wiring pattern 16 formed by photolithography and etching after Cu plating is performed on the Cu foil of the resin film 11 with Cu foil. Further, the high heat dissipation plastic package 10 is provided with a solder resist film 17 on the surface on which the conductor wiring pattern 16 is formed in order to expose a necessary portion of the conductor wiring pattern 16 from the opening.
[0015]
As shown in FIGS. 2A to 2C, a high heat dissipation plastic package 10a of a modification according to an embodiment of the present invention includes a semiconductor in addition to the structure of the high heat dissipation plastic package 10 described above. A conductor wiring pattern 16a is also provided on the lower surface side of the heat radiating plate 12a for radiating heat generated from the element. In this case, the heat radiating plate 12a is previously provided with a through hole 18 for a through hole 19 for establishing electrical continuity between the upper and lower conductor wiring patterns 16 and 16a using a drill or the like. In the through hole 18, electrical continuity between the upper and lower conductor wiring patterns 16 and 16 a is formed by conductor wiring formed so as not to be short-circuited on the wall surface of the through hole 18. Further, similar to the case of the high heat dissipation plastic package 10, the heat radiating plate 12 a is generated in the cavity portion 14 when bonded to the adhesive resin 13 formed by bonding to the resin film 11 with Cu foil. A restraining portion is provided for preventing resin seepage.
[0016]
The high heat dissipation plastic package 10a can be configured as a cavity-up type package in which a semiconductor element is mounted on the upper surface side and an external connection terminal such as a solder ball is connected to the lower surface side, and heat generated from the semiconductor element is efficiently radiated. At the same time, the size of the package can be made extremely small by effectively using both sides of the package. The high heat radiation type plastic package 10a of this modification may be formed on the basis of a Cu foil in which a conductor wiring pattern 16a on the lower surface side is bonded via a prepreg. The wiring pattern 16a may be formed based on the resin film 11 with Cu foil.
[0017]
Here, referring to FIGS. 3 (A) and 3 (B), the heat radiating plates 12, 12a of the high heat radiating plastic package 10 and the modified high heat radiating plastic package 10a according to the embodiment of the present invention are restrained. 20 forms will be described. 3A and 3B, the high heat dissipation plastic package 10 will be described as a representative. As shown in FIG. 3 (A), the heat radiating plate 12 used in the high heat radiating type plastic package 10 has a resin film 11 with Cu foil slightly on the periphery of the notch 15 provided in the resin film 11 with Cu foil. It is preferable to have the restraining part 20 which consists of the level | step difference 21 which can be mounted | worn with this clearance. Due to the step 21, the cavity portion 14 on which the semiconductor element of the heat radiating plate 12 is mounted is formed in a convex shape higher than the portion to which the resin film 11 with Cu foil is joined. When the resin film 11 with Cu foil is heat-pressed to the heat radiating plate 12, the resin oozing of the adhesive resin 13 is blocked by the restraining portion 20 composed of the step 21, thereby reducing the oozing of the resin onto the cavity portion 14. be able to.
[0018]
Further, as shown in FIG. 3B, the heat sink 12 used in the high heat dissipation plastic package 10 has a resin film 11 with Cu foil and a peripheral edge of a notch 15 provided in the resin film 11 with Cu foil. It is good to have the stop part 20 which consists of the groove | channel 22 formed along. This groove 22 forms an isolation part between the cavity part 14 where the semiconductor element of the heat sink 12 is mounted and the part where the resin film 11 with Cu foil is joined. The resin bleed out of the adhesive resin 13 when the resin film 11 with Cu foil is heat-pressed to the heat sink 12 can drop the resin into the restraining portion 20 composed of the groove 22, so that the resin bleed onto the cavity portion 14. The stock can be reduced. In addition, the form of the restraining part 20 formed in the heat sink 12 may have a groove 22 and a cavity part 14 formed in a convex shape higher than the part to which the resin film 11 with Cu foil is joined. Good.
[0019]
Next, a method for manufacturing the high heat dissipation plastic package 10 according to one embodiment of the present invention will be described with reference to FIGS.
As shown in FIG. 4 (A), a resin film 11 with Cu foil for bonding to the heat radiating plate 12 to produce the high heat radiating plastic package 10 is made of glass cloth on a Cu foil 23 having a thickness of about 10 to 20 μm. A thermosetting B-stage adhesive resin 13 that does not include a base material is applied to about 50 to 100 μm by a doctor blade method, a roll coater method, or the like to form a film. In addition, when Cu foil is heat-treated in a reducing atmosphere in advance, it is possible to obtain a stable peeling strength with high bonding strength after bonding the adhesive resin 13.
[0020]
Next, as shown in FIG. 4 (B), a cutout 15 for a cavity portion 14 (see FIG. 4 (E)) for mounting a semiconductor element is punched in the resin film 11 with Cu foil. Etc. are provided by drilling. Since the resin film 11 with Cu foil is a joined body of the Cu foil 23 and the adhesive resin 13, the resin does not contain glass cloth or the like, and the joined body itself is thin. The notch 15 can be formed efficiently and accurately at low cost by punching a processing machine.
[0021]
Next, as shown in FIG. 4C, the heat sink 12 made of a metal member having a high thermal conductivity such as Cu or Cu alloy and having a thickness of about 0.2 mm is an example of the restraining portion 20. For example, a portion that becomes the cavity portion 14 is formed in a convex shape by etching, cutting, or the like. As a result, a step 21 is formed around the periphery of the convex cavity portion 14 so as to follow the periphery of the notch 15 provided in the Cu foil-attached resin film 11 with a slight clearance. A restraining portion 20 is formed for preventing the resin 13 from sticking out. Although not shown, the restraining portion 20 may be formed by a groove 22 (see FIG. 3B) formed by, for example, etching or cutting. Further, the heat radiation plate 12 may be improved in bonding strength when the surface is roughened by a honing process or black oxide or the like and bonded to the adhesive resin 13.
[0022]
Next, as shown in FIG. 4D, the resin film 11 with Cu foil and the heat radiating plate 12 directly contact the heat radiating plate 12 with the bonding resin 13 side of the resin film with Cu foil 11 and vacuum press or the like. Is used for thermocompression bonding. When thermocompression bonding is performed using a vacuum press machine, for example, the degree of vacuum is set to 50 mmHg or less, and heating and pressurization are maintained for 40 minutes or more in a temperature of 170 to 190 ° C., a pressure of 2 to 3 MPa, and a temperature of 175 ° C. or more. The adhesive resin 13 is cured and bonded. By this thermocompression bonding, a resin ooze occurs in the adhesive resin 13, but the resin ooze is stopped by the stop portion 20 to reduce the resin bleed onto the cavity portion 14.
[0023]
Next, as shown in FIG. 4 (E), after Cu plating (not shown) made of electroless Cu plating and electric field Cu plating is applied on the Cu foil 23 of the resin film 11 with Cu foil, The conductor wiring pattern 16 is formed by normal semi-additive, subtractive, or the like. Furthermore, a solder resist film 17 is formed on the surface on which the conductor wiring pattern 16 is formed in order to expose a necessary portion of the conductor wiring pattern 16 from the opening, whereby the high heat dissipation plastic package 10 is manufactured. . Since the high heat radiation type plastic package 10 is formed in a large number on the sheet-like base material, it is finally cut at the cutting portion 24 after the semiconductor element or the like is mounted.
[0024]
Next, a manufacturing method of the high heat radiation type plastic package 10a of the modification according to the embodiment of the present invention will be described with reference to FIGS.
As shown in FIG. 5A, the resin film 11 with Cu foil for producing the high heat dissipation plastic package 10a is coated with the adhesive resin 13 on the Cu foil 23 as in the case of the high heat dissipation plastic package 10. Thus, the film is produced, and the notch 15 is formed by a punching press.
[0025]
Next, as shown in FIG. 5B, the cavity plate 12a made of a metal member having a high thermal conductivity such as Cu or Cu alloy has a cavity portion as in the case of the high heat dissipation plastic package 10. 14 is formed in a convex shape, and a restraining portion 20 is formed on the peripheral edge of the cavity portion 14 to prevent the resin 13 from adhering to the stepped portion 21 from leaking out. Although not shown, as in the case of the high heat dissipation plastic package 10, the restraining portion 20 may be formed by, for example, a groove 22 (see FIG. 3B). The heat radiating plate 12a is provided with a through hole 18 for a through hole 19 for establishing electrical continuity between the conductor wiring patterns 16 and 16a on the upper and lower surfaces of the package (see FIG. 5E). It is formed using. Furthermore, the surface of the heat radiating plate 12a is roughened by honing, black oxide, or the like. And the prepreg 25 and Cu foil 23a for forming the conductor wiring pattern 16a of the lower surface side are prepared in the lower surface side of the heat sink 12a.
[0026]
Next, as shown in FIG. 5C, the adhesive resin 13 of the Cu foil-attached resin film 11 in which the notch 15 is formed is brought into direct contact with the surface on the upper surface side of the heat radiating plate 12a. The Cu foil 23a is brought into contact with the surface on the lower surface side of the plate 12a through the prepreg 25, and is pressurized while being heated using a vacuum press or the like in the same manner as in the case of the high heat radiation type plastic package 10, so Bonded and bonded together. By this bonding, the through holes 18 of the heat radiating plate 12 a are filled with the adhesive resin 13 and the prepreg 25. By this thermocompression bonding, a resin ooze occurs in the adhesive resin 13, but the resin ooze is stopped by the stop portion 20 to reduce the resin bleed onto the cavity portion 14.
[0027]
Next, as shown in FIG. 5 (D), a through-hole having a diameter smaller than the diameter of the through-hole 18 so that the wall surface of the through-hole 18 filled with the adhesive resin 13 or the prepreg 22 is covered with the resin. A hole 26 for the hole 19 is drilled with a drill machine or the like. Then, the Cu foil 23 and the Cu plating film 27 on the upper surface side and the Cu Cu on the lower surface side are passed through the through hole 19 in which the electroless Cu plating and the electric field Cu plating are performed and the Cu plating film 27 is formed on the wall surface of the hole 26. The foil 23a and the Cu plating film 27 are electrically connected.
[0028]
Next, as shown in FIG. 5E, as in the case of the high heat dissipation plastic package 10, the Cu foil 23 and the Cu plating film 27 on the upper surface side, and the Cu foil 23a and the Cu plating film 27 on the lower surface side are formed. Conductor wiring patterns 16 and 16a are formed on both sides by a normal semi-additive method, a subtractive method, or the like. Furthermore, solder resist films 17 and 17a are formed on the surface on which the conductor wiring patterns 16 and 16a are formed in order to expose the necessary portions of the conductor wiring patterns 16 and 16a from the openings, so that a high heat dissipation type plastic package is formed. 10a is produced.
[0029]
As in the case of the high heat dissipation plastic package 10, the high heat dissipation plastic package 10 a is formed in a large number on the sheet-like base material, so that it is finally cut after the semiconductor element or the like is mounted. It is made by cutting at a location 24. Also, a thermal via (not shown) that is connected to the heat sink 12a and exposed from the opening of the solder resist film 17a is provided below the cavity portion 14 where the semiconductor element is mounted, thereby generating heat from the semiconductor element. The effect of radiating heat can be further improved. Further, on the back surface side of the heat sink 12a below the cavity portion 14 on which the semiconductor element is mounted, a convex portion (not shown) similar to the restraining portion 20 including the step 21 provided on the upper surface side of the heat sink 12a. ) And a thermal via (not shown) similar to the above can be provided. Thereby, while being able to improve the heat dissipation effect of the heat generated from the semiconductor element, it is possible to prevent warpage of the heat sink 12a by forming uniform convex portions on both surfaces of the heat sink 12a. Further, in the manufacturing method of the high heat dissipation plastic package 10a, the prepreg 25 and the Cu foil 23a are used to form the conductor wiring pattern 16a on the lower surface side of the heat radiating plate 12a. You may form using the resin film 11 with Cu foil similar to the resin film 11 with Cu foil used in order to form 16. FIG.
[0030]
Next, another manufacturing method of the high heat dissipation plastic package 10 and the modified high heat dissipation plastic package 10a according to the embodiment of the present invention will be described with reference to FIGS. 6A to 6D, another manufacturing method using the high heat dissipation plastic package 10 will be described as a representative.
As shown in FIG. 6A, the resin film 11 with Cu foil for producing the high heat dissipation plastic package 10 is obtained by applying the adhesive resin 13 to the Cu foil 23 as in the case of all the packages described above. A cut-out 15 is formed in the resin film 11 with Cu foil by a punching press machine.
[0031]
Next, as shown in FIG. 6 (B), it is made of a metal member having a high thermal conductivity such as Cu or Cu alloy in order to dissipate heat generated from the semiconductor element, and the surface is formed by honing or black oxide. A heat radiating plate 12 capable of improving the bonding strength when the surface is roughened and bonded to the adhesive resin 13 is prepared. Moreover, the convex part 28 which can be fitted to the notch 15 formed in the resin film 11 with Cu foil is provided, and the holding jig 29 formed with resin or metal is prepared. Furthermore, a low melting point resin film 30 and a release film 31 for sandwiching between the holding jig 29 and the resin film 11 with Cu foil are prepared.
[0032]
Next, as shown in FIG. 6C, the resin film 11 with Cu foil is placed on the heat sink 12 so that the adhesive resin 13 side of the resin film 11 with Cu foil is in contact with the heat sink 12. Furthermore, the release film 31 through the low melting point resin film 30 is placed on the cavity portion 14 and the resin film 11 with Cu foil, and is pressed from above the low melting point resin film 30 with a pressing jig 29. Since the convex portion 28 of the holding jig 29 is fitted in the notch 15 of the Cu foil-attached resin film 11, the cavity portion 14 is formed by the release film 31 through the low melting point resin film 30 by the convex portion 28. Can be sealed. Then, in this state, the adhesive resin 13 is heated to join the Cu foil-attached resin film 11 and the heat radiating plate 12, and the resin ooze into the cavity portion 14 of the adhesive resin 13 is removed from the low melting point resin film 30. It is stopped by a release film 31 interposed.
[0033]
Next, as shown in FIG. 6 (D), after joining the resin film 11 with Cu foil and the heat sink 12, the holding jig 29 is removed, and further the release film 31 via the low melting point resin film 30 is removed. is doing. Thereafter, the high heat dissipation plastic package 10 and the modified high heat dissipation plastic package 10a are manufactured in the same manner as the above-described manufacturing method.
[0034]
【The invention's effect】
According to the present invention A high heat dissipation plastic package is formed by bonding an adhesive resin to a Cu foil, and a resin film with a Cu foil having a notch for a cavity portion and a heat sink are directly bonded by an adhesive resin. The heat dissipation plate has a restraining portion for preventing the resin seepage during the bonding of the resin film with the Cu foil to the adhesive resin, and therefore the resin film with the Cu foil and the heat dissipation plate. Since no post-adhesive adhesive such as a prepreg is used for the bonding, a package with a thin package, a low cost, and a high heat radiation type plastic package with high bonding accuracy can be provided. In addition, it is possible to prevent the resin from bleeding into the cavity during bonding of the adhesive resin, and to improve the mounting reliability of the semiconductor element.
[0035]
Further, according to the present invention The high heat dissipation plastic package has a notch in the stop. clearance Therefore, it is possible to prevent the resin from bleeding into the cavity portion of the adhesive resin at the step portion that can be formed in the cavity portion, and to improve the mounting reliability of the semiconductor element.
[0036]
Also, According to the present invention The high heat dissipation plastic package consists of a groove formed along the periphery of the notch in the high heat dissipation type plastic package, which prevents the resin from seeping into the cavity part of the adhesive resin at the groove and improves the mounting reliability of the semiconductor element. Can be improved.
[0037]
According to the present invention The manufacturing method of the high heat dissipation type plastic package is to directly bond the resin film with Cu foil formed by bonding the resin for bonding to the Cu foil and drilling the notch for the cavity portion, and the heat sink. A step of forming a step or a groove along the periphery of the notch of the resin film with Cu foil on the heat sink, and heating the adhesive resin. While joining the resin film with the Cu foil and the heat sink, and having a step of stopping the resin oozing of the resin for bonding with a step or groove, it can be easily and accurately bonded to the heat sink with the adhesive resin at once, Thin and inexpensive high heat dissipation plastic packages can be manufactured. In addition, it is possible to prevent the occurrence of the resin oozing out of the adhesive resin on the heat sink of the cavity portion by the step or the groove portion, and it is possible to mount the semiconductor element with high bonding reliability, and to efficiently dissipate heat generated from the semiconductor element. High heat dissipation plastic package can be manufactured.
[0038]
The method of manufacturing a high heat radiation type plastic package according to claim 5 includes: bonding a resin for bonding to a Cu foil and forming a notch for a cavity portion to form a Cu foil-attached resin film and a heat sink. A method of manufacturing a high heat radiation type plastic package formed by directly bonding with a resin for a resin, wherein a release film via a low melting point resin film is formed by using a holding jig having a convex portion that can be fitted into a notch, and a cavity portion and The process of pressing on the resin film with Cu foil, and heating the adhesive resin to join the resin film with Cu foil and the heat sink, and restraining the resin oozing out of the adhesive resin with the release film through the low melting point resin film And the step of removing the pressing jig and the step of removing the release film via the low-melting point resin film. , Accurately, can joined at a time, it can be produced small thickness inexpensive high heat dissipation plastic package. In addition, it is possible to prevent the occurrence of resin oozing out of the adhesive resin on the heat sink of the cavity with a release film via a low melting point resin film pressed by a holding jig. In addition, a high heat radiation type plastic package capable of efficiently radiating heat generated from the semiconductor element can be manufactured.
[Brief description of the drawings]
1A and 1B are a perspective view and a longitudinal sectional view, respectively, of a high heat dissipation plastic package according to an embodiment of the present invention.
FIGS. 2A to 2C are a top perspective view, a bottom perspective view, and a longitudinal sectional view, respectively, of a high heat dissipation plastic package of the same modification.
FIGS. 3A and 3B are explanatory views of a restraining portion of a heat radiating plate of the high heat dissipation plastic package and a modified high heat dissipation plastic package, respectively.
4A to 4E are explanatory views of a method for manufacturing the same high heat dissipation plastic package, respectively.
FIGS. 5A to 5E are explanatory views of a manufacturing method of a high heat radiation type plastic package of the same modification example, respectively.
6A to 6D are explanatory views of another manufacturing method of the high heat dissipation plastic package and a modified high heat dissipation plastic package, respectively.
7A to 7D are explanatory views of a conventional method for manufacturing a high heat dissipation plastic package.
[Explanation of symbols]
10, 10a: High heat dissipation plastic package, 11: Resin film with Cu foil, 12, 12a: Heat dissipation plate, 13: Adhesive resin, 14: Cavity part, 15: Notch, 16, 16a: Conductor wiring pattern, 17 17a: Solder resist film, 18: Through hole, 19: Through hole, 20: Stopping part, 21: Step, 22: Groove, 23, 23a: Cu foil, 24: Cut location, 25: Prepreg, 26: Hole, 27: Cu plating film, 28: convex part, 29: holding jig, 30: low melting point resin film, 31: release film

Claims (7)

A conductor formed of a Cu foil and a Cu plating film formed by bonding a resin for bonding to a Cu foil and having a notch for a cavity for mounting a semiconductor element in a substantially central portion in plan view. A resin film with a Cu foil on which a wiring pattern is formed, a metal heat radiating plate that is directly bonded to the lower surface of the adhesive resin of the resin film with a Cu foil and radiates heat generated from the semiconductor element, and It has a prepreg bonded to the lower surface of the heat sink and formed with a Cu foil and a conductor wiring pattern made of a Cu plating film , and the heat sink provides electrical continuity between the conductor wiring patterns formed on the upper and lower surfaces. a through hole for a through hole Cu plated film is formed for the contact adhesive resin and prepreg inside this through hole through holes are filled during the bonding, respectively, the heat dissipation When, a high heat dissipation plastic package carrying insulation between Cu plating film in the respective conductor wiring pattern formed on the upper and lower surfaces and the through hole in the resin and prepreg the contact wear,
The heat radiating plate has a restraining portion for preventing a resin ooze out when the resin film with Cu foil is joined to the adhesive resin, and the restraining portion has a clearance in the notch and the cavity portion. A high heat dissipation type plastic package characterized in that the step is formed so that the semiconductor element can be mounted. A conductor formed of a Cu foil and a Cu plating film formed by bonding a resin for bonding to a Cu foil and having a notch for a cavity for mounting a semiconductor element in a substantially central portion in plan view. A resin film with a Cu foil on which a wiring pattern is formed, a metal heat radiating plate that is directly bonded to the lower surface of the adhesive resin of the resin film with a Cu foil and radiates heat generated from the semiconductor element, and It has a prepreg bonded to the lower surface of the heat sink and formed with a Cu foil and a conductor wiring pattern made of a Cu plating film , and the heat sink provides electrical continuity between the conductor wiring patterns formed on the upper and lower surfaces. a through hole for a through hole Cu plated film is formed for the contact adhesive resin and prepreg inside this through hole through holes are filled during the bonding, respectively, the heat dissipation When, a high heat dissipation plastic package carrying insulation between Cu plating film in the respective conductor wiring pattern formed on the upper and lower surfaces and the through hole in the resin and prepreg the contact wear,
The heat radiating plate has a restraining portion for preventing a resin ooze out when the resin film with Cu foil is joined to the adhesive resin, and the restraining portion is a groove formed along the periphery of the notch. High heat dissipation plastic package characterized by comprising A resin film with Cu foil formed by bonding a resin for bonding to a Cu foil, and forming a notch for a cavity for mounting the semiconductor element in a substantially central portion in plan view, and the semiconductor element a metal heat dissipating plate for dissipating heat generated from a method for producing a high heat dissipation plastic package formed by joining directly with the adhesive resin,
The heat sink has a through hole for a through hole and a step along the periphery of the notch of the resin film with Cu foil, and a cavity is formed in the notch to form a cavity. Forming a step where the element can be mounted;
One surface of the heat sink and the adhesive resin portion of the resin film with Cu foil formed with the notch are directly contacted, and at the same time, the other surface of the heat sink is contacted with Cu foil via a prepreg. Bonding by thermocompression bonding, filling the through hole for the through hole with the adhesive resin and prepreg, and stopping the resin oozing of the adhesive resin at the step; and
After this bonding step, a hole for a through hole is formed so that the wall surface of the through hole for the through hole of the heat sink is covered with the filled adhesive resin and prepreg , and Cu plating is provided in this hole. Forming a film, bringing the Cu foils on the upper and lower surfaces of the heat sink into a conductive state, forming a conductor wiring pattern on the resin film with Cu foil, and forming a conductor wiring pattern on the Cu foil via the prepreg A method of manufacturing a high heat dissipation type plastic package, comprising a step of forming. A resin film with Cu foil formed by bonding a resin for bonding to a Cu foil, and forming a notch for a cavity for mounting the semiconductor element in a substantially central portion in plan view, and the semiconductor element a metal heat dissipating plate for dissipating heat generated from a method for producing a high heat dissipation plastic package formed by joining directly with the adhesive resin,
Forming a through hole for the through hole in the heat sink and a groove along the periphery of the cutout of the resin film with the Cu foil;
One surface of the heat sink and the adhesive resin portion of the resin film with Cu foil formed with the notch are directly contacted, and at the same time, the other surface of the heat sink is contacted with Cu foil via a prepreg. Bonding by thermocompression bonding, filling the through hole for the through hole with the adhesive resin and prepreg, and stopping the resin oozing of the adhesive resin in the groove; and
After this bonding step, a hole for a through hole is formed so that the wall surface of the through hole for the through hole of the heat sink is covered with the filled adhesive resin and prepreg , and Cu plating is provided in this hole. Forming a film, bringing the Cu foils on the upper and lower surfaces of the heat sink into a conductive state, forming a conductor wiring pattern on the resin film with Cu foil, and forming a conductor wiring pattern on the Cu foil via the prepreg A method of manufacturing a high heat dissipation type plastic package, comprising a step of forming. A resin film with Cu foil formed by bonding a resin for bonding to a Cu foil, and forming a notch for a cavity for mounting the semiconductor element in a substantially central portion in plan view, and the semiconductor element A heat radiating plate for radiating heat generated from a direct heat bonding with the adhesive resin, and a manufacturing method of a high heat radiation type plastic package,
Pressing the release film onto the cavity part and the resin film with Cu foil using a pressing jig having a convex part that can be fitted into the notch of the resin film with Cu foil;
Heating the adhesive resin to join the Cu foil-attached resin film and the heat sink, and stopping the resin exudation of the adhesive resin with the release film;
A method for producing a high heat dissipation plastic package, comprising removing the pressing jig and removing the release film. A Cu foil and a Cu plating film are formed by bonding a first adhesive resin to a Cu foil and having a notch for a cavity for mounting a semiconductor element in a substantially central portion in plan view. A first Cu foil-coated resin film on which a first conductor wiring pattern is formed, and the first Cu foil-fitted resin film directly bonded to the lower surface of the first adhesive resin, from the semiconductor element A metal heat radiating plate for radiating the heat generated from the heat radiating member and a lower surface of the heat radiating plate are bonded to each other, and a second adhesive resin is bonded to the Cu foil. A second Cu foil-fitted resin film on which the conductor wiring pattern is formed, and the heat sink is formed with a Cu plating film for electrical conduction between the first and second conductor wiring patterns. It includes a through-hole through holes to be The said inside the through-hole through holes first and second contact adhesive resin is filled at the time of bonding between the first and second Cu foil resin film and the heat radiating plate, said heat radiating plate , a high heat dissipation plastic package carrying the insulation between the first and second Cu plated film conductor wiring patterns and in the through hole in the first and second contact adhesive resin,
The heat radiating plate has a restraining portion for preventing resin seepage during the joining of the resin film with the first Cu foil to the first adhesive resin, and the restraining portion has a clearance in the notch. A high heat radiating plastic package, characterized in that it has a step which can form the cavity portion and mount the semiconductor element. A Cu foil and a Cu plating film are formed by bonding a first adhesive resin to a Cu foil and having a notch for a cavity for mounting a semiconductor element in a substantially central portion in plan view. A first Cu foil-coated resin film on which a first conductor wiring pattern is formed, and the first Cu foil-fitted resin film directly bonded to the lower surface of the first adhesive resin, from the semiconductor element A metal heat radiating plate for radiating the heat generated from the heat radiating member and a lower surface of the heat radiating plate are bonded to each other, and a second adhesive resin is bonded to the Cu foil. A second Cu foil-fitted resin film on which the conductor wiring pattern is formed, and the heat sink is formed with a Cu plating film for electrical conduction between the first and second conductor wiring patterns. It includes a through-hole through holes to be The said inside the through-hole through holes first and second contact adhesive resin is filled at the time of bonding between the first and second Cu foil resin film and the heat radiating plate, said heat radiating plate , a high heat dissipation plastic package carrying the insulation between the first and second Cu plated film conductor wiring patterns and in the through hole in the first and second contact adhesive resin,
The heat radiating plate has a restraining portion for preventing a resin seepage during the joining of the resin film with the first Cu foil to the first adhesive resin, and the restraining portion is provided at the periphery of the notch. A high heat radiation type plastic package characterized by comprising grooves formed along.

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