KR20240068192A - Ceramic substrate for power module and manufacturing method thereof - Google Patents

Abstract

The present invention relates to a ceramic substrate for a power module and a method of manufacturing the same. The ceramic substrate for a power module according to an embodiment of the present invention includes a ceramic substrate and a groove configured to be bonded to the upper surface of the ceramic substrate and to mount a semiconductor device. It may include an upper electrode provided with a lower electrode that is bonded to the lower surface of the ceramic substrate and has a plurality of protrusions provided on the lower surface to correspond to the groove.

Description

Ceramic substrate for power module and manufacturing method thereof {CERAMIC SUBSTRATE FOR POWER MODULE AND MANUFACTURING METHOD THEREOF}

The present invention relates to a ceramic substrate and a manufacturing method thereof, and more specifically, to a ceramic substrate for a power module in which a lower electrode provided with a plurality of protrusions for water-cooled heat dissipation, a ceramic substrate, and an upper electrode are integrated, and a manufacturing method thereof. .

In general, electric vehicles require an inverter that converts direct current voltage provided by a high-voltage battery into alternating current three-phase voltage to drive the motor.

This inverter is assembled with a power module to adjust and supply the high voltage of the driving battery to a state suitable for the motor. The power module includes semiconductor chips for power conversion, and these semiconductor chips generate high temperature heat due to high voltage and high current operation. If this heat continues, the semiconductor chip deteriorates and the performance of the power module deteriorates.

To solve this problem, a heat sink is provided on at least one side of the ceramic or metal substrate to prevent deterioration of the semiconductor chip due to heat through the heat dissipation function of the heat sink.

Heat sinks are made of metal materials with high thermal conductivity, such as copper and aluminum. Heat sinks made of these metals also have limitations in heat dissipation, so when heat exceeding the limit is generated, cooling efficiency drops rapidly, causing malfunctions.

In addition, in the case of the substrate on which the semiconductor chip is mounted, there is a problem in that the characteristics are deteriorated due to warping due to heat.

Registered Patent Publication No. 10-1896569 (registered on September 3, 2018)

The present invention was made to solve the above-mentioned problems, and its purpose is to provide a ceramic substrate for a power module and a manufacturing method thereof that can effectively dissipate heat generated from a semiconductor chip.

A ceramic substrate for a power module according to an embodiment of the present invention for achieving the above-described object includes a ceramic substrate, an upper electrode bonded to the upper surface of the ceramic substrate and provided with a groove configured to mount a semiconductor device; It may include a lower electrode that is bonded to the lower surface of the ceramic substrate and has a plurality of protrusions provided on the lower surface to correspond to the grooves.

The depth of the groove may be formed to correspond to the thickness of the semiconductor device.

Additionally, the groove includes a plurality of side surfaces and a bottom surface connected to the plurality of side surfaces, and the semiconductor device may be bonded to the bottom surface through a bonding layer.

The depth of the groove may be equal to the sum of the thickness of the semiconductor device and the thickness of the bonding layer.

The bonding layer may be an AuSn solder layer or a sintered layer formed by sintering silver paste.

The area of the groove may be formed to be the same as the area of the semiconductor device.

The area of the lower electrode where the plurality of protrusions are disposed may be formed to be equal to the area of the groove.

The area of the lower electrode where the plurality of protrusions are disposed may be smaller than the area of the groove.

Each of the upper and lower electrodes may have a thickness of 0.5 mm or more and 9.0 mm or less.

The plurality of protrusions are disposed in the external refrigerant circulation unit, and the liquid refrigerant circulating through the refrigerant circulation unit can exchange heat with the plurality of protrusions.

Each of the plurality of protrusions may be formed to have a narrower width toward the lower portion.

A plurality of grooves may be arranged in parallel at intervals. Here, the groove includes a first groove and a second groove, and the plurality of protrusions include a plurality of first protrusions provided on the lower surface of the lower electrode to correspond to the first groove, and a plurality of protrusions provided on the lower surface of the lower electrode to correspond to the second groove. It may include a plurality of second protrusions.

A method of manufacturing a ceramic substrate according to an embodiment of the present invention includes preparing a ceramic substrate, preparing an upper electrode having a groove configured to mount a semiconductor device, and a plurality of protrusions provided on the lower surface to correspond to the groove. It may include preparing a lower electrode provided with a, bonding the upper electrode to the upper surface of the ceramic substrate, and bonding the lower electrode to the lower surface of the ceramic substrate.

In the step of preparing the upper electrode, the depth of the groove can be formed to correspond to the thickness of the semiconductor device.

In the step of preparing the upper electrode, the depth of the groove may be formed equal to the sum of the thickness of the semiconductor device and the thickness of the bonding layer that joins the semiconductor device.

In the step of preparing the upper electrode, the area of the groove may be formed to be the same as the area of the semiconductor device.

In the step of preparing the lower electrode, the area of the area where the plurality of protrusions are disposed may be formed to be the same as the area of the groove.

In the step of preparing the lower electrode, the area of the area where the plurality of protrusions are disposed may be formed to be smaller than the area of the groove.

According to the ceramic substrate for a power module according to an embodiment of the present invention, a plurality of protrusions corresponding to the size and position of the semiconductor device are formed on the lower electrode to directly cool the semiconductor device, thereby improving local cooling efficiency for the semiconductor device.

In addition, according to the ceramic substrate for a power module according to an embodiment of the present invention, the upper electrode is provided with a groove configured to mount a semiconductor element, so that the distance between the semiconductor element and the protrusion of the lower electrode can be minimized to increase cooling efficiency. The thickness of the power module, including semiconductor elements and ceramic substrates, can be made as thin as possible, making it possible to produce power modules with high heat dissipation, high efficiency, and high reliability while realizing weight reduction and miniaturization.

In addition, according to the ceramic substrate for a power module according to an embodiment of the present invention, there is no need to machine a groove on the entire lower surface of the lower electrode as grooves are machined only in a portion of the area overlapping with the semiconductor device, thereby simplifying the process and improving the quality of the semiconductor device. It is possible to directly cool the area where the most heat is generated, thereby increasing the heat dissipation effect.

In addition, according to the ceramic substrate for a power module according to an embodiment of the present invention, since the plurality of protrusions of the lower electrode is a water-cooled heat dissipation structure in which the plurality of protrusions of the lower electrode are cooled by directly contacting the continuously circulating liquid refrigerant, the flow rate of the liquid refrigerant can be varied to provide rapid cooling. It can absorb and dissipate heat.

Figure 1 is a perspective view showing a ceramic substrate for a power module according to an embodiment of the present invention.
Figure 2 is an exploded perspective view showing a ceramic substrate for a power module according to an embodiment of the present invention.
Figure 3 is an exploded perspective view of Figure 2 seen from the bottom side.
Figure 4 is a side view and a partial enlarged view showing a ceramic substrate for a power module according to an embodiment of the present invention.
Figure 5 is a cross-sectional view taken along line A-A' in Figure 1.
Figure 6 is a partial enlarged view of area A of Figure 5.
FIG. 7 is a partial enlarged view showing a state in which the semiconductor elements in FIG. 6 are bonded.
Figure 8 is a bottom view and a partial enlarged view showing a ceramic substrate for a power module according to an embodiment of the present invention.
Figure 9 is a conceptual diagram showing a configuration in which a ceramic substrate for a power module according to an embodiment of the present invention is mounted on the refrigerant circulation unit, and a circulation drive unit is connected to the refrigerant circulation unit.
Figure 10 is a cross-sectional view showing a modified example in which the area of the area where the plurality of protrusions are disposed is formed to be equal to the area of the groove in the ceramic substrate for a power module according to an embodiment of the present invention.
Figure 11 is a cross-sectional view showing a comparative example in which the area of the area where the plurality of protrusions are arranged is larger than the area of the groove in the ceramic substrate for a power module according to an embodiment of the present invention.
Figure 12 is a plan view showing a ceramic substrate for a power module according to another embodiment of the present invention.
Figure 13 is a bottom view showing a ceramic substrate for a power module according to another embodiment of the present invention.
Figure 14 is a flowchart showing a method of manufacturing a ceramic substrate for a power module according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings.

The examples are provided to more completely explain the present invention to those skilled in the art, and the following examples may be modified in various other forms, and the scope of the present invention is limited to the following examples. It is not limited. Rather, these embodiments are provided to make the disclosure more faithful and complete and to fully convey the spirit of the invention.

The terms used herein are used to describe specific embodiments and are not intended to limit the invention. Additionally, in this specification, singular forms may include plural forms, unless the context clearly indicates otherwise.

In the description of the embodiment, each layer (film), region, pattern or structure is said to be formed “on” or “under” the substrate, each layer (film), region, pad or pattern. Where described, “on” and “under” include both being formed “directly” or “indirectly” through another layer. In addition, in principle, the standards for the top or bottom of each floor are based on the drawing.

The drawings are only intended to enable understanding of the spirit of the present invention, and should not be construed as limiting the scope of the present invention by the drawings. Additionally, in the drawings, relative thickness, length, or relative size may be exaggerated for convenience and clarity of explanation.

FIG. 1 is a perspective view showing a ceramic substrate for a power module according to an embodiment of the present invention, FIG. 2 is an exploded perspective view showing a ceramic substrate for a power module according to an embodiment of the present invention, and FIG. 3 is FIG. 2 is an exploded perspective view seen from the bottom side, Figure 4 is a side view and a partial enlarged view showing a ceramic substrate for a power module according to an embodiment of the present invention, and Figure 5 is a cross-sectional view taken along line A-A' in Figure 1. , FIG. 6 is a partial enlarged view of area A of FIG. 5, FIG. 7 is a partial enlarged view showing the state in which the semiconductor elements are bonded in FIG. 6, and FIG. 8 is an enlarged view of the area A of FIG. 5 according to an embodiment of the present invention. This is a bottom view and partially enlarged view showing a ceramic substrate for a power module.

1 to 4, the ceramic substrate 1 for a power module according to an embodiment of the present invention includes a ceramic substrate 100 and upper and lower electrodes 200 and 300 on the upper and lower surfaces 110 and 120 of the ceramic substrate 100. ) may be an AMB (Active Metal Brazing) substrate. The embodiment is described using an AMB substrate as an example, but a DBC (Direct Bonding Copper) substrate can also be applied. AMB substrates are most suitable in terms of durability and efficiency in dissipating heat generated from semiconductor chips.

The ceramic substrate 100 may be made of an oxide-based or nitride-based ceramic material. For example, the ceramic substrate 100 may be formed of any insulating material selected from the group consisting of alumina (Al ₂ O ₃ ), AlN, Si ₃ N ₄ , and Zirconia Toughened Alumina (ZTA), which have high thermal conductivity and excellent flexural strength. there is. The thickness of the ceramic substrate 100 may be 0.32 mm, but is not limited thereto.

The upper electrode 200 may be configured to be bonded to the upper surface 110 of the ceramic substrate 100 and to mount the semiconductor device 10 on it. Specifically, the upper electrode 200 may be provided with a groove 210 at a location where the semiconductor device 10 is mounted.

Referring to Figures 5 and 6, the groove 210 includes a plurality of side surfaces 212 and a bottom surface 211 connected to the plurality of side surfaces 212, and may be formed, for example, in the shape of a rectangular parallelepiped. The groove 210 may be dug to a certain depth t so that the semiconductor device 10 can be inserted. When there is only one groove 210 formed in the upper electrode 200, the semiconductor devices 10 can be connected in series.

Referring to FIG. 7 , the depth t of the groove 210 may be formed to correspond to the thickness of the semiconductor device 10 . For example, the depth (t) of the groove 210 may be 0.1 mm. The depth t of the groove 210 may be equal to the sum of the thickness of the semiconductor device 10 and the thickness of the bonding layer 20. Additionally, the depth of the groove 210 may be formed to be the same as the thickness of the semiconductor device 10. The area of the groove 210 may be smaller than or equal to the area of the semiconductor device. In this way, by machining the groove 210 only in a portion of the area facing the semiconductor device 10, there is no need to machine the groove 210 on the entire lower surface of the lower electrode 300, thereby simplifying the process and manufacturing the semiconductor device 10. Since it is possible to directly cool the area where the most heat is generated, the heat dissipation effect can be improved.

The groove 210 can be formed by applying mechanical processing methods such as cutting processing or press processing, or can be formed by applying chemical etching processing. Here, the groove 210 may be formed before the upper electrode 200 is bonded to the ceramic substrate 100, or may be formed after the upper electrode 200 is bonded to the ceramic substrate 100.

In this way, when the upper electrode 200 is provided with the groove 210 corresponding to the size of the semiconductor element 10, the semiconductor element 10 is accommodated and mounted inside the upper electrode 200, so that the power module The thickness can be made as thin as possible, eliminating thickness restrictions.

In addition, the ceramic substrate 1 for a power module according to an embodiment of the present invention has a plurality of protrusions 310 provided on the lower electrode 300 to correspond to the grooves 210 of the upper electrode 200. As will be described later, the plurality of protrusions 310 can be forcibly cooled by continuously circulating liquid refrigerant to directly cool the heat generated in the semiconductor device 10. At this time, when the groove 210 is formed in the upper electrode 200, the distance between the semiconductor device 10 and the protrusion 310 can be reduced as much as possible. That is, since the semiconductor device 10 is mounted on the bottom surface 211 of the groove 210 provided inside the upper electrode 200, compared to when the semiconductor device 10 is mounted on the top surface of the upper electrode 200 The distance between the semiconductor element 10 and the protrusion 310 can be minimized to increase cooling efficiency. In addition, the thickness of the power module including the semiconductor element 10 and the ceramic substrate 1 can be formed as thin as possible, enabling miniaturization, and increasing local cooling efficiency for the semiconductor element 10 to prevent it from affecting surrounding elements. can do.

The upper electrode 200 may be provided with a thickness of 0.5 mm or more and 9.0 mm or less. In this way, when the thickness of the upper electrode 200 to which the semiconductor device 10 is bonded is formed to be relatively thick, high voltage and high current can be passed. When high-output power conversion is performed, the upper electrode 200 must have high electrical conductivity and high thermal conductivity for heat dissipation. In the ceramic substrate according to an embodiment of the present invention, the upper electrode 200 is formed of any one material of Cu, Al, and Cu alloy with high thermal conductivity, and is formed with a relatively thick thickness of 0.5 mm or more and 9.0 mm or less. It has excellent electrical and thermal conductivity and can be applied to high-output power conversion power modules. In addition, since the upper electrode 200 is provided with a thickness of 0.5 mm or more and 9.0 mm or less, it is easy to form grooves 210 of various depths corresponding to the thickness of the semiconductor device 10 and the thickness of the bonding layer 20. do.

The semiconductor device 10 may be one of an insulated gate bipolar transistor (IGBT), SiC, GaN, or gallium nitride semiconductor (GaN on SiC). The semiconductor device 10 may be bonded to the bottom surface 211 of the groove 210 via the bonding layer 20. Here, the bonding layer 20 may be a solder layer made of a soldering material such as AuSn or a sintered layer formed by sintering silver paste. When the bonding layer 20 is formed of an AuSn solder layer, the AuSn solder layer is disposed between the bottom surface 211 of the groove 210 and the lower surface of the semiconductor device 10, and then AuSn solder layer is formed at a temperature of about 220° C. As the solder layer melts, the semiconductor device 10 may be joined. Additionally, when the bonding layer 20 is silver paste, the semiconductor device 10 can be bonded by Ag sintering. In the heat sintering method using silver paste, the silver paste is placed between the bottom surface 211 of the groove 210 and the bottom surface of the semiconductor element 10, and is pressurized at a pressure of about 15Mpa and heated to a temperature of about 250 ° C. By doing this, joining can be achieved at the joining surface.

The upper electrode 200 may be bonded to the upper surface 110 of the ceramic substrate 100 via a brazing filler layer (not shown). The brazing filler layer is disposed between the lower surface of the upper electrode 200 and the upper surface 110 of the ceramic substrate 100, and can integrally bond the upper electrode 200 and the ceramic substrate 100 at the brazing temperature. The brazing temperature may be carried out at 450°C or higher, preferably between 780°C and 900°C. The brazing filler layer may be formed of a material containing at least one of Ag, Cu, AgCu, and AgCuTi, and may have a thickness of about 20 μm to 100 μm. Ag, AgCu, and AgCuTi have high thermal conductivity, which increases bonding strength and at the same time facilitates heat transfer between the upper electrode 200 and the ceramic substrate 100 to increase heat dissipation efficiency.

The lower electrode 300 may be bonded to the lower surface 120 of the ceramic substrate 100 and may be formed of any one material of Cu, Al, or Cu alloy with high thermal conductivity.

The lower electrode 300 is provided in a flat form to increase bonding strength by maximizing the bonding area with the ceramic substrate 100, and can be formed to have a thickness of 0.5 mm or more and 9.0 mm or less. Additionally, the lower electrode 300 may have a plurality of protrusions 310 provided on its lower surface to correspond to the grooves 210 .

When the lower electrode 300 is formed with a relatively thick thickness of 0.5 mm or more and 9.0 mm or less, the heat dissipation area is expanded and heat is spread evenly, making it effective in dissipating heat. For example, the lower electrode 300 may have a thickness of 0.6 mm, and the upper electrode 200 may have a thickness of 0.8 mm, so they may be provided differently. Additionally, the thickness of the lower electrode 300 may be 0.8 mm, and the thickness of the upper electrode 200 may be 0.8 mm.

Referring to FIG. 8, the plurality of protrusions 310 are provided to dissipate heat generated by the semiconductor device 10, and may be formed to protrude at intervals from each other on the lower surface of the lower electrode 300. Here, it is preferable that the distance (a) between the protrusions 310 is 0.12 mm or more, the distance (b) between the center points of the protrusions 310 is 0.42 mm or more, and the diameter (c) of the protrusions 310 is 0.3 mm or more. . Additionally, the thickness of the protrusion 310 is preferably 0.1 mm or more. For example, if the thickness of the lower electrode 300 is 0.8 mm, the thickness of the protrusion 310 may be processed to 0.25 mm.

The plurality of protrusions 310 may be formed to have a narrower width toward the lower portion. Since the liquid refrigerant moves between the plurality of protrusions 310, the flow rate and cooling efficiency of the liquid refrigerant can be easily controlled depending on the shape of the plurality of protrusions 310. If the protrusion 310 is formed to have a narrower width toward the lower portion, the flow rate of the liquid refrigerant passing through the space between the protrusion 310 may become faster toward the upper portion closer to the semiconductor device 10. Meanwhile, the plurality of protrusions 310 may be provided in various pin shapes such as a cylinder, polygonal column, teardrop shape, or diamond shape. Additionally, the plurality of protrusions 310 may be provided in a bar shape and may be provided in the form of slits arranged horizontally at intervals from each other.

The lower electrode 300 may be bonded to the lower surface 120 of the ceramic substrate 100 via a brazing filler layer (not shown). The brazing filler layer is disposed between the lower surface 120 of the ceramic substrate 100 and the upper surface of the lower electrode 300, and can integrally bond the ceramic substrate 100 and the lower electrode 300 at the brazing temperature. The brazing temperature may be carried out at 450°C or higher, preferably between 780°C and 900°C. The brazing filler layer may be formed of a material containing at least one of Ag, Cu, AgCu, and AgCuTi, and may have a thickness of about 20 μm to 100 μm. Ag, AgCu, and AgCuTi have high thermal conductivity, which increases bonding strength and at the same time facilitates heat transfer between the ceramic substrate 100 and the lower electrode 300 to increase heat dissipation efficiency.

Figure 9 is a conceptual diagram showing a configuration in which a ceramic substrate for a power module according to an embodiment of the present invention is mounted on the refrigerant circulation unit, and a circulation drive unit is connected to the refrigerant circulation unit.

As shown in FIG. 9 , a plurality of protrusions 310 may be disposed in the refrigerant circulation unit 2 in the ceramic substrate for a power module according to an embodiment of the present invention. The refrigerant circulation unit 2 may be provided with an inlet 2a through which liquid refrigerant flows, an outlet 2b through which liquid refrigerant is discharged, and an internal flow path (not shown) from the inlet 2a to the outlet 2b. At this time, the liquid refrigerant flowing in through the inlet (2a) of the refrigerant circulation unit (2) may be discharged through the outlet (2b) through the internal flow path. Since the shape and size of the internal flow path, which is the path through which the liquid refrigerant moves between the inlet (2a) and the outlet (2b), can be designed in various ways, a detailed description of the internal flow path itself of the refrigerant circulation unit (2) will be omitted. Do this.

The circulation drive unit 3 is connected to the refrigerant circulation unit 2 and can circulate liquid refrigerant using the driving force of a pump (not shown). Here, the inlet (2a) of the refrigerant circulation unit (2) may be connected to the circulation drive unit (3) through the first circulation line (L1), and the outlet (2b) of the refrigerant circulation unit (2) may be connected to the second circulation line (L1). It can be connected to the circulation drive unit (3) through L2). That is, the circulation drive unit 3 can continuously circulate the liquid refrigerant along a circulation path including the first circulation line (L1), the refrigerant circulation unit (2), and the second circulation line (L2). Here, the liquid refrigerant may be deionized water, but is not limited thereto, and liquid nitrogen, alcohol, or other solvents may be used as needed.

The liquid refrigerant supplied from the circulation drive unit (3) flows into the inlet (2a) of the refrigerant circulation unit (2) through the first circulation line (L1), and moves along the internal flow path formed in the refrigerant circulation unit (2) to the outlet. It is discharged through (2b) and can then move back to the circulation drive unit (3) through the second circulation line (L2). Although not shown in detail, the circulation drive unit 3 may include a heat exchanger (not shown). The heat exchanger of the circulation drive unit (3) can lower the temperature of the liquid refrigerant whose temperature has risen while passing through the internal flow path of the refrigerant circulation unit (2), and the circulation drive unit (3) can transfer the liquid refrigerant whose temperature has been lowered by the heat exchanger to the pump. It can be supplied back to the first circulation line (L1) using the driving force.

In this way, the refrigerant circulation unit 2 may be provided so that the liquid refrigerant supplied from the circulation drive unit 3 circulates continuously. At this time, the plurality of protrusions 310 are disposed within the internal flow path of the refrigerant circulation unit 2 and can directly contact and exchange heat with the liquid refrigerant continuously circulating along the internal flow path. That is, the plurality of protrusions 310 have a water-cooled heat dissipation structure that can be directly cooled by continuously circulating liquid refrigerant.

The plurality of protrusions 310 are forcibly cooled by the continuously circulating liquid refrigerant even if high-temperature heat is generated from the semiconductor device 10 mounted in the groove 210 of the upper electrode 200, so that the semiconductor device 10 does not deteriorate. It can be maintained at a constant temperature. In other words, even if high temperature heat of about 100°C or more is generated in the semiconductor device 10, the temperature of the liquid refrigerant circulating along the internal flow path of the refrigerant circulation unit 2 is about 25°C, so the heat of the semiconductor device 10 is quickly dissipated. It can be cooled.

Figure 10 is a cross-sectional view showing a modified example in which the area of the area where the plurality of protrusions are disposed is formed to be equal to the area of the groove in the ceramic substrate for a power module according to an embodiment of the present invention, and Figure 11 is an embodiment of the present invention. This is a cross-sectional view showing a comparative example in which the area of the area where the plurality of protrusions are arranged is larger than the area of the groove in the ceramic substrate for a power module according to the example.

Referring to FIG. 10, the area of the area B where the plurality of protrusions 310 are disposed in the lower electrode 300 of the ceramic substrate 1 for a power module according to the modified example is the same as the area of the groove 210. can be formed. That is, when viewed from the top, the area B where the plurality of protrusions 310 are disposed may overlap the groove 210. In this way, by machining the groove 210 only in a portion of the area facing the semiconductor device 10, there is no need to machine the groove 210 on the entire lower surface of the lower electrode 300, thereby simplifying the process and manufacturing the semiconductor device 10. Since it is possible to directly cool the area where the most heat is generated, the heat dissipation effect can be improved.

Referring to FIG. 11, the area of the area B where the plurality of protrusions 310 are disposed in the lower electrode 300 of the ceramic substrate 1 for a power module according to the comparative example is formed to be larger than the area of the groove 210. It can be. In this way, when the area of the area B where the plurality of protrusions 310 are arranged is larger than the area of the groove 210, there is a difference in heat dissipation performance compared to when the area of the groove 210 is smaller than or equal to the area of the groove 210. It is inefficient because there is no processing area of the groove 210 and the processing time increases as the processing area of the groove 210 becomes larger. Therefore, it is most efficient for the area of the area B where the plurality of protrusions 310 are arranged to be smaller than or equal to the area of the groove 210.

The ceramic substrate 1 for a power module according to an embodiment of the present invention has a pin-fin structure in which a lower electrode 300, a ceramic substrate 100, and an upper electrode 200 are integrated, and is a semiconductor device. Since the structure directly cools the heat of the semiconductor device 10 locally using a plurality of protrusions 310 corresponding to the size and position of the device 10, heat dissipation performance can be improved while achieving weight reduction and miniaturization.

In addition, the ceramic substrate 1 for a power module according to an embodiment of the present invention is provided with a groove 210 configured to mount the semiconductor element 10 on the upper electrode 200, and the bottom surface of the groove 210 ( Since the semiconductor device 10 is mounted on 211, the distance between the semiconductor device 10 and the protrusion 310 is minimized, which has the advantage of further increasing cooling efficiency. In addition, the ceramic substrate 1 for the power module has a water-cooled heat dissipation structure, so it can quickly absorb and dissipate heat by varying the flow rate of the liquid refrigerant.

Figure 12 is a top view showing a ceramic substrate for a power module according to another embodiment of the present invention, and Figure 13 is a bottom view showing a ceramic substrate for a power module according to another embodiment of the present invention.

12 and 13, in the ceramic substrate 1' for a power module according to another embodiment of the present invention, the upper electrode 200' has a first groove 210a' and a second groove 210b'. It can be provided. A plurality of first grooves 210a' and second grooves 210b' may be arranged in parallel at intervals. As such, when the first groove 210a' and the second groove 210b' are arranged in parallel on the upper electrode 200', a semiconductor element is formed in each of the first groove 210a' and the second groove 210b'. is mounted, allowing parallel connection of semiconductor devices.

The lower electrode 300' includes a plurality of first protrusions 310a' provided on the lower surface of the lower electrode 300' to correspond to the first groove 210a', and a lower electrode to correspond to the second groove 210b'. It may be configured to include a plurality of second protrusions 310b' provided on the lower surface of 300'. In this way, the positions and quantities of the grooves 210a' and 210b' and the protrusions 310a' and 310b' may be implemented in various ways depending on the positions and quantities of semiconductor devices determined during circuit design.

Figure 14 is a flowchart showing a method of manufacturing a ceramic substrate for a power module according to an embodiment of the present invention.

As shown in FIG. 14, the method of manufacturing a ceramic substrate for a power module according to an embodiment of the present invention includes preparing a ceramic substrate 100 (S10) and forming a groove 210 configured to mount the semiconductor device 10. A step (S20) of preparing an upper electrode 200 provided with a step (S30) of preparing a lower electrode 300 provided with a plurality of protrusions 310 provided on the lower surface to correspond to the groove 210, It may include bonding the upper electrode 200 to the upper surface 110 of the ceramic substrate 100 and bonding the lower electrode 300 to the lower surface 120 of the ceramic substrate 100 (S40). Here, the step of preparing the ceramic substrate 100 (S10), the step of preparing the upper electrode 200 (S20), and the step of preparing the lower electrode 300 (S30) are performed sequentially or in reverse order. may be performed, and may be performed substantially simultaneously.

In the step of preparing the ceramic substrate 100 (S10), the ceramic substrate 100 may be made of an oxide-based or nitride-based ceramic material. For example, the ceramic substrate 100 may be formed of any insulating material selected from the group consisting of alumina (Al ₂ O ₃ ), AlN, Si ₃ N ₄ , and Zirconia Toughened Alumina (ZTA), which have high thermal conductivity and excellent flexural strength. there is.

In the step (S20) of preparing the upper electrode 200 having a groove 210 configured to mount the semiconductor device 10, the upper electrode 200 is made of any one of Cu, Al, and Cu alloys with high thermal conductivity. Because it is made of material and has a relatively thick thickness of 0.5 mm to 9.0 mm, it has excellent electrical and thermal conductivity and can be applied to high-output power conversion power modules.

In the step S20 of preparing the upper electrode 200, the depth of the groove 210 may be formed to correspond to the thickness of the semiconductor device 10. For example, the depth of the groove 210 may be equal to the sum of the thickness of the semiconductor device 10 and the thickness of the bonding layer 20 that bonds the semiconductor device 10. Additionally, the depth of the groove 210 may be formed to be the same as the thickness of the semiconductor device 10. The area of the groove 210 may be formed to be the same as the area of the semiconductor device 10. The groove 210 can be formed by applying mechanical processing methods such as cutting processing or press processing, or can be formed by applying chemical etching processing.

In the step (S30) of preparing the lower electrode 300 having a plurality of protrusions 310 provided on the lower surface to correspond to the groove 210, the lower electrode 300 has a bonding area with the ceramic substrate 100 as large as possible. It is provided in a flat form to increase bonding strength, and can be formed to have a thickness of 0.5 mm or more and 9.0 mm or less. The lower electrode 300 may have a plurality of protrusions 310 provided on its lower surface to correspond to the grooves 210 . The plurality of protrusions 310 are provided to dissipate heat generated from the semiconductor device 10, and may be formed to protrude at intervals from each other on the lower surface of the lower electrode 300. These plurality of protrusions 310 may be disposed within the internal flow path of the refrigerant circulation unit 2 and provided to directly contact the liquid refrigerant continuously circulating along the internal flow path.

In the step S30 of preparing the lower electrode 300, the area of the area B where the plurality of protrusions 310 are disposed may be smaller than or equal to the area of the groove 210. As shown in FIGS. 5 and 10 , when the area of the area B where the plurality of protrusions 310 are disposed is smaller than or equal to the area of the groove 210, the entire lower surface of the lower electrode 300 Since there is no need to process the groove 210, the process is simplified, and the heat dissipation effect can be increased because the part of the semiconductor device 10 that generates the most heat can be directly cooled.

In the step (S40) of bonding the upper electrode 200 to the upper surface 110 of the ceramic substrate 100 and the lower electrode 300 to the lower surface 120 of the ceramic substrate 100, a brazing filler layer is disposed. It may include a step of joining and a brazing joining step.

The step of disposing the brazing filler layer may include disposing a brazing filler layer formed of a material containing at least one of Ag, Cu, AgCu, and AgCuTi by any one of plating, paste application, and foil attachment. At this time, the brazing filler layer can be disposed between the lower surface of the upper electrode 200 and the upper surface 110 of the ceramic substrate 100, and between the lower surface 120 of the ceramic substrate 100 and the upper surface of the lower electrode 300. .

After disposing the bonding layer 20, a step of melting the bonding layer 20 and joining the upper electrode 200, the ceramic substrate 100, and the lower electrode 300 by brazing may be performed. In the brazing joining step, the lower electrode 300, the ceramic substrate 100, and the upper electrode 200 are stacked and the brazing filler layer interposed between each layer is melted at 450°C or higher and 780°C to 900°C. Brazing can be done, and at this time, top weight or pressure can be applied to increase the bonding strength.

As such, the ceramic substrate 1 for a power module according to an embodiment of the present invention has a pin-fin structure in which the lower electrode 300, the ceramic substrate 100, and the upper electrode 200 are integrated. , Since the structure directly cools the heat of the semiconductor device locally using a plurality of protrusions 310 corresponding to the size and position of the semiconductor device, heat dissipation performance can be improved while realizing weight reduction and miniaturization.

In addition, the ceramic substrate 1 for a power module according to an embodiment of the present invention is provided with a groove 210 configured to mount a semiconductor element on the upper electrode 200, and has a groove 210 on the bottom surface 211 of the groove 210. Since the semiconductor device is mounted, the distance between the semiconductor device and the protrusion 310 is minimized, which has the advantage of further increasing cooling efficiency. In addition, the ceramic substrate 1 for the power module has a water-cooled heat dissipation structure, so it can quickly absorb and dissipate heat by varying the flow rate of the liquid refrigerant.

The above description is merely an illustrative explanation of the technical idea of the present invention, and various modifications and variations will be possible to those skilled in the art without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but are for illustrative purposes, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be construed as being included in the scope of rights of the present invention.

1,1': Ceramic substrate for power module 10: Semiconductor device
20: Bonding layer 100,100': Ceramic substrate
110,110': Top surface of ceramic substrate 120,120': Bottom surface of ceramic substrate
200,200': upper electrode 210: groove
210a': first groove 210b': second groove
211: bottom surface 212: side
300: lower electrode 310: protrusion
310a': first protrusion 310b': second protrusion

Claims (19)

ceramic substrate;
an upper electrode bonded to the upper surface of the ceramic substrate and having a groove configured to mount a semiconductor device; and
a lower electrode bonded to the lower surface of the ceramic substrate and having a plurality of protrusions provided on the lower surface to correspond to the grooves;
A ceramic substrate for a power module containing. According to paragraph 1,
A ceramic substrate for a power module in which the depth of the groove is formed to correspond to the thickness of the semiconductor element. According to paragraph 1,
The groove includes a plurality of sides and a bottom surface connected to the plurality of sides,
A ceramic substrate for a power module wherein the semiconductor element is bonded to the bottom surface through a bonding layer. According to paragraph 3,
A ceramic substrate for a power module in which the depth of the groove is equal to the sum of the thickness of the semiconductor element and the thickness of the bonding layer. According to paragraph 3,
A ceramic substrate for a power module in which the bonding layer is a sintered layer formed by sintering an AuSn solder layer or a silver paste. According to paragraph 1,
A ceramic substrate for a power module in which the area of the groove is formed to be the same as the area of the semiconductor element. According to paragraph 1,
A ceramic substrate for a power module in which the area of the lower electrode where the plurality of protrusions are disposed is formed to be equal to the area of the groove. According to paragraph 1,
A ceramic substrate for a power module wherein the area of the lower electrode where the plurality of protrusions are arranged is smaller than the area of the groove. According to paragraph 1,
A ceramic substrate for a power module, wherein each of the upper electrode and the lower electrode has a thickness of 0.5 mm or more and 9.0 mm or less. According to paragraph 1,
The plurality of protrusions are disposed in the external refrigerant circulation section,
A ceramic substrate for a power module in which liquid refrigerant circulating through the refrigerant circulation unit exchanges heat with the plurality of protrusions. According to paragraph 1,
A ceramic substrate for a power module, wherein each of the plurality of protrusions is formed to have a narrower width toward the lower portion. According to paragraph 1,
A ceramic substrate for a power module in which a plurality of the grooves are arranged in parallel at intervals. According to clause 12,
The groove includes a first groove and a second groove,
The plurality of protrusions are,
a plurality of first protrusions provided on the lower surface of the lower electrode to correspond to the first grooves; and
A ceramic substrate for a power module including a plurality of second protrusions provided on a lower surface of the lower electrode to correspond to the second groove. Preparing a ceramic substrate;
Preparing an upper electrode having a groove configured to mount a semiconductor device;
preparing a lower electrode having a plurality of protrusions provided on a lower surface to correspond to the groove; and
Bonding the upper electrode to the upper surface of the ceramic substrate and bonding the lower electrode to the lower surface of the ceramic substrate;
A method of manufacturing a ceramic substrate for a power module comprising. According to clause 14,
In the step of preparing the upper electrode,
A method of manufacturing a ceramic substrate for a power module in which the depth of the groove is formed to correspond to the thickness of the semiconductor device. According to clause 14,
In the step of preparing the upper electrode,
A method of manufacturing a ceramic substrate for a power module, wherein the depth of the groove is equal to the sum of the thickness of the semiconductor device and the thickness of the bonding layer that joins the semiconductor device. According to clause 14,
In the step of preparing the upper electrode,
A method of manufacturing a ceramic substrate for a power module, wherein the area of the groove is formed to be the same as the area of the semiconductor device. According to clause 14,
In the step of preparing the lower electrode,
A method of manufacturing a ceramic substrate for a power module, wherein the area of the area where the plurality of protrusions are disposed is formed to be the same as the area of the groove. According to clause 14,
In the step of preparing the lower electrode,
A method of manufacturing a ceramic substrate for a power module, wherein the area of the area where the plurality of protrusions are disposed is formed to be smaller than the area of the groove.

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