KR20230105364A - Ceramic substrate unit and manufacturing method thereof - Google Patents

Abstract

The present invention relates to a ceramic substrate unit and a manufacturing method thereof, wherein the ceramic substrate unit includes a ceramic substrate provided with metal layers on upper and lower surfaces of a ceramic substrate, a heat dissipation spacer bonded to the upper metal layer of the ceramic substrate, and bonded to the lower metal layer of the ceramic substrate. and a heat sink, and the heat dissipation spacer is provided with an electrode in a region where the semiconductor chips are bonded, so that the semiconductor chips can be bonded in a flip chip form.

Description

Ceramic substrate unit and its manufacturing method {CERAMIC SUBSTRATE UNIT AND MANUFACTURING METHOD THEREOF}

The present invention relates to a ceramic substrate unit and a manufacturing method thereof, and more particularly, to a ceramic substrate unit having a bonding structure between a ceramic substrate and a heat sink having a plurality of protrusions for water-cooled heat dissipation, and a manufacturing method thereof.

In general, electric vehicles require an inverter that converts DC voltage provided from a high-voltage battery into AC three-phase voltage for driving a motor.

Such an inverter is assembled with a power module for adjusting and supplying a high voltage of a driving battery to a state suitable for a motor. The power module includes a semiconductor chip for power conversion, and the semiconductor chip generates high-temperature heat due to high-voltage and high-current operation. If this heat continues, there is a problem in that 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 surface of a ceramic or metal substrate to prevent deterioration of a semiconductor chip due to heat through a heat dissipation function of the heat sink.

Heat sinks are made of metal materials with high thermal conductivity, such as copper and aluminum. Even heat sinks made of these metals have limitations in heat dissipation.

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

Matters described in the background art above are intended to help understand the background of the invention, and may include matters that are not disclosed prior art.

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

The present invention has been made to solve the above problems, and an object of the present invention is to provide a ceramic substrate unit capable of effectively dissipating heat generated from a semiconductor chip and a manufacturing method thereof.

A ceramic substrate unit according to an embodiment of the present invention for achieving the above object is a ceramic substrate having metal layers on upper and lower surfaces of a ceramic substrate, a heat dissipation spacer bonded to the upper metal layer of the ceramic substrate, and a lower portion of the ceramic substrate. It includes a heat sink bonded to the metal layer, and the heat dissipation spacer is provided with an electrode in a region where the semiconductor chip is bonded, so that the semiconductor chip can be bonded in a flip chip form.

The heat dissipation spacer may bond at least two semiconductor chips.

The heat dissipation spacer has a shape corresponding to the upper metal layer, and is disposed at a position facing a first heat dissipation spacer having a lower surface bonded to the upper metal layer and having wiring parts including electrodes and one end of the electrode, and a semiconductor chip on the upper surface. It may include at least one second heat dissipation spacer to which the electrode is bonded.

The wiring unit may include an insulating layer disposed in a groove formed on an upper portion of the first heat dissipating spacer and formed of an insulating material, and an electrode disposed on the upper portion of the insulating layer and extending from one end along the groove to form a wire.

The electrodes may be disposed to be inserted at a predetermined depth in the upper surface of the insulating layer, provided as a pair, and spaced apart in the width direction of the insulating layer.

The heat sink may include a flat portion having an upper surface in contact with the lower metal layer and a plurality of protrusions disposed on a lower surface of the flat portion at a distance from each other and forming a passage through which a liquid refrigerant flows.

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

The plurality of protrusions may be provided in a bar shape and may be horizontally disposed at intervals from each other.

In addition, the plurality of protrusions may be provided in a pin shape of at least one of a cylinder shape, a polygonal column shape, a teardrop shape, and a diamond shape.

The material of the heat sink may be any one of Cu, Al, and Cu alloy.

The heat dissipation spacer may be made of Cu, MoCu, or a CPC material in which Cu, CuMo, and Cu are sequentially stacked.

It may further include a first bonding layer disposed between the upper metal layer of the ceramic substrate and the heat dissipation spacer, and the first bonding layer may be made of a material including at least one of Ag, Cu, AgCu, and AgCuTi, or may be made of Ag sintering paste. there is.

It further includes a second bonding layer disposed between the lower metal layer of the ceramic substrate and the planar portion of the heat sink, wherein the second bonding layer is made of a material containing at least one of Ag, Cu, AgCu, and AgCuTi, or Ag sintering paste. can be made with

A method of manufacturing a ceramic substrate unit according to an embodiment of the present invention includes preparing a ceramic substrate having metal layers on upper and lower surfaces of a ceramic substrate, and preparing a heat dissipation spacer having electrodes for bonding semiconductor chips in a flip chip shape. The method may include bonding the heat dissipation spacer to the upper metal layer of the ceramic substrate, and bonding the heat sink to the lower metal layer of the ceramic substrate.

In the step of preparing the heat dissipation spacer, the heat dissipation spacer has a shape corresponding to the upper metal layer, the lower surface is bonded to the upper metal layer, and the first heat dissipation spacer having a wiring part including an electrode is disposed at a position facing one end of the electrode. and at least one second heat dissipation spacer to which an electrode of a semiconductor chip is bonded to an upper surface thereof.

In the step of preparing the heat dissipation spacer, an insulating layer disposed in a groove formed on an upper portion of the first heat dissipating spacer and formed of an insulating material, disposed on an upper portion of the insulating layer, and extending from one end along the groove to form a wire electrodes may be included.

In the step of preparing the heat dissipation spacer, the electrodes may be disposed to be inserted to a predetermined depth in the upper surface of the insulating layer, provided as a pair, and spaced apart in the width direction of the insulating layer.

In the bonding of the heat dissipation spacer to the upper metal layer of the ceramic substrate, the heat dissipation spacer is bonded to the upper metal layer via a first bonding layer disposed between the upper metal layer and the heat dissipation spacer, and the first bonding layer includes Ag, Cu, AgCu, and AgCuTi. It may be made of a material containing at least one of, or may be made of Ag sintering paste.

In the bonding of the heat sink to the lower metal layer of the ceramic substrate, the heat sink is bonded to the lower metal layer via a second bonding layer disposed between the lower metal layer and the flat surface of the heat sink, and the second bonding layer includes Ag, Cu , AgCu and AgCuTi, or Ag sintering paste.

According to the present invention, an electrode is provided in a region where a semiconductor chip is bonded in a heat dissipation spacer, and the semiconductor chip is bonded in a flip chip form, thereby omitting wire bonding, thereby reducing an inductance value as much as possible and improving heat dissipation performance. In addition, the rated voltage and current can be converted while removing electrical hazards that may occur during wire bonding, and reliability and efficiency can be improved when used at high power.

In addition, according to the present invention, heat generated from the semiconductor chip is transferred to the ceramic substrate and the heat sink through the heat dissipation spacer, thereby increasing heat dissipation efficiency.

In addition, since the present invention is a water-cooled heat dissipation structure in which a plurality of protrusions are directly contacted and cooled by a continuously circulating liquid-type refrigerant, it is possible to quickly absorb and dissipate heat by adjusting the flow rate of the liquid-type refrigerant, and to dissipate heat in a conventional air-cooled heat dissipation manner. Compared to the structure, the heat dissipation effect can be maximized.

In addition, according to the present invention, even if high-temperature heat is generated from a semiconductor chip or the like, it is forcibly cooled by a continuously circulating liquid refrigerant to prevent overheating of the ceramic substrate and to maintain the semiconductor chip at a constant temperature so as not to deteriorate.

In addition, since the liquid refrigerant is provided to move between the plurality of protrusions, the flow rate and cooling efficiency of the liquid refrigerant can be easily controlled by changing the shape, number, and arrangement of the plurality of protrusions.

1 is a plan side perspective view showing a ceramic substrate unit according to an embodiment of the present invention.
2 is a bottom side perspective view showing a ceramic substrate unit according to an embodiment of the present invention.
3 is a side view illustrating a ceramic substrate unit according to an embodiment of the present invention.
4 is a plan view illustrating a ceramic substrate unit according to an embodiment of the present invention.
5 is a cross-sectional view taken along the line A-A' of FIG. 3;
6 is a conceptual diagram illustrating a configuration in which a ceramic substrate unit according to an embodiment of the present invention is mounted on a refrigerant circulation unit and a circulation driving unit is connected to the refrigerant circulation unit.
7 is a flowchart illustrating a method of manufacturing a ceramic substrate unit according to an embodiment of the present invention.

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

1 is a planar side perspective view showing a ceramic substrate unit according to an embodiment of the present invention, FIG. 2 is a bottom side perspective view showing a ceramic substrate unit according to an embodiment of the present invention, and FIG. 3 is an embodiment of the present invention FIG. 4 is a plan view illustrating a ceramic substrate unit according to an embodiment of the present invention, and FIG. 5 is a cross-sectional view taken along line AA′ of FIG. 3 .

As shown in FIGS. 1 to 3 , a ceramic substrate unit 1 according to an embodiment of the present invention may include a ceramic substrate 100 , a heat radiation spacer 200 and a heat sink 300 .

The ceramic substrate 100 may be any one of an active metal brazing (AMB) substrate, a direct bonded copper (DBC) substrate, and a thick printing copper (TPC) substrate. These substrates are substrates in which a metal is directly bonded to a ceramic substrate. In an embodiment of the present invention, the ceramic substrate 100 includes a ceramic substrate 110 and an upper metal layer 120 and a lower metal layer 130 on the upper and lower surfaces of the ceramic substrate 110 to increase heat dissipation efficiency of the semiconductor chip. ) may be provided.

The ceramic substrate 110 may be made of an oxide-based or nitride-based ceramic material. For example, the ceramic substrate 110 may be any one of alumina (Al ₂ O ₃ ), AlN, SiN, Si ₃ N ₄ , ZTA (Zirconia Toughened Alumina), but is not limited thereto.

The upper metal layer 120 and the lower metal layer 130 may be made of one of Cu, Al, and Cu alloys having excellent thermal conductivity, but are not limited thereto.

The upper metal layer 120 is formed on the upper surface of the ceramic substrate 110 and may be provided in a circuit pattern shape. For example, the upper metal layer 120 may be formed as an electrode pattern in an area where a semiconductor chip or a peripheral component is to be mounted.

The lower metal layer 130 is formed on the lower surface of the ceramic substrate 110 and may be provided as a flat plate to facilitate heat transfer. Since the volume difference between the lower metal layer 130 in the form of a flat plate is larger than the total volume of the upper metal layer 120 formed of the electrode pattern, the ceramic substrate 100 may be bent in a high-temperature environment. Therefore, according to the present invention, by brazing the heat sink 300 to be described later and the ceramic substrate 100 integrally, it is possible to suppress a warping phenomenon caused by a volume difference between the upper and lower metal layers 120 and 130 .

The heat dissipation spacer 200 is bonded to the upper metal layer 120 of the ceramic substrate 100, and an electrode 211b is provided in a region where the semiconductor chip c (see FIG. 6) is bonded so that the semiconductor chip c is flipped. It can be bonded in the form of a chip (flip chip). At this time, the heat dissipation spacer 200 may be bonded to at least two semiconductor chips c.

Specifically, the heat dissipation spacer 200 may include a first heat dissipation spacer 210 and at least one second heat dissipation spacer 220 .

The first heat dissipation spacer 210 may have a shape corresponding to the upper metal layer 120 of the ceramic substrate 100 and may have a lower surface bonded to the upper metal layer 120 and may have a predetermined thickness for heat dissipation.

Referring to FIGS. 4 and 5 , the first heat dissipation spacer 210 may include a wiring part 211 . The wiring part 211 may be disposed in the groove h formed on the top of the first heat dissipation spacer 210 .

Here, the wiring unit 211 may include an insulating layer 211a and an electrode 211b. The insulating layer 211a may be disposed in the groove h formed on the first heat dissipation spacer 210 and made of an insulating material. For example, PI (Polyimide), FR4, Ceramic (Alumina, ZTA, AlN, Si ₃ N ₄ , etc.) may be used as the insulating layer, but is not limited thereto.

The electrode 211b may be disposed on the insulating layer 211a. Here, the electrodes 211b may be arranged to be inserted to a certain depth in the upper surface of the insulating layer 211a, and may be provided as a pair and spaced apart in the width direction of the insulating layer 211a.

The electrode 211b may extend along the groove h of the first heat dissipation spacer 210 from one end disposed at a position facing the second heat dissipation spacer 220 to form a wire. That is, since one end of the electrode 211b is disposed at a position facing the second heat dissipation spacer 220, the electrode 211b is connected to the semiconductor chip c bonded to the second heat dissipation spacer 220 to serve as an electric line for transmitting an electric signal. can do. For example, the electrode 211b may be made of Cu, Ag, Ni-Au, W, Mo, or MoW, but is not limited thereto.

At least one second heat dissipation spacer 220 may be disposed at a position facing one end of the electrode 211b, and an electrode of the semiconductor chip c may be bonded to the upper surface. Here, the second heat dissipation spacer 220 may be connected to the gate terminal of the semiconductor chip c, and the first heat dissipation spacer 210 may serve as a source or drain in charge of high current input/output.

The semiconductor chip (c) bonded to the second heat dissipation spacer 220 may be a semiconductor chip such as SiC, GaN, Si, LED, or VCSEL. The semiconductor chip (c) has a flip chip shape on the upper surface of the second heat dissipation spacer 220 by a bonding layer (b) including solder or silver paste (see FIG. 6). can be joined with

At least one second heat dissipation spacer 220 may be formed by bonding to a position facing one end of the electrode 211b on the top surface of the first heat dissipation spacer 210 or formed integrally with the first heat dissipation spacer 210. can The second heat dissipation spacer 220 may be provided in the form of a small block having a size of 0.5 mmx0.5 mm or more and a thickness of 0.3 mm or more. The second heat dissipation spacer 220 may be processed to an appropriate size by etching, and further machining may be performed if necessary.

As described above, in the present invention, since the electrode 211b is provided on the heat dissipation spacer 200 and bonded to the semiconductor chip (c) in the form of a flip chip, wire bonding is omitted, so that the inductance value can be reduced as much as possible and the heat dissipation performance can be improved. . In addition, the rated voltage and current can be converted while removing electrical hazards that may occur during wire bonding, and reliability and efficiency can be improved when used at high power. In addition, heat generated from the semiconductor chip (c) is transferred to the ceramic substrate 100 and the heat sink 300 through the heat dissipation spacer 200, so that heat dissipation efficiency may be increased.

The heat dissipation spacer 200 may be made of at least one of Cu, Al, AlSiC, CuMo, CuW, Cu/CuMo/Cu, Cu/Mo/Cu, and Cu/W/Cu, or a composite material thereof. Preferably, the heat dissipation spacer 200 may be formed of at least one of Cu, Mo, CuMo alloy, and CuW alloy having excellent thermal expansion coefficient and thermal conductivity.

For example, the heat dissipation spacer 200 may have a three-layer structure of Cu/CuMo/Cu. The CPC material in which Cu, CuMo, and Cu are sequentially laminated has high thermal conductivity, is advantageous for heat dissipation, and has a low coefficient of thermal expansion, thereby minimizing warpage during brazing bonding with the upper metal layer 120 of the ceramic substrate 100.

The heat dissipation spacer 200 may be provided in a state in which thermal stress, thermal deformation, and the like are removed in advance through heat treatment. If thermal stress and thermal strain are removed in advance, thermal stress generated by thermal expansion and contraction in the process of brazing bonding the upper metal layer 120 of the ceramic substrate 100 and the heat dissipation spacer 200 is relieved to improve bonding strength. can make it In addition, since the bonding area is not damaged, the heat transfer effect becomes excellent.

The heat dissipation spacer 200 may be bonded to the upper metal layer 120 of the ceramic substrate 100 via the first bonding layer 10 . In this case, the first bonding layer 10 may be a brazing bonding layer or an Ag sintering bonding layer made of a material including at least one of Ag, Cu, AgCu, and AgCuTi. When the first bonding layer 10 is a brazing bonding layer, the brazing bonding layer may be disposed between the upper metal layer 120 of the ceramic substrate 100 and the first heat dissipation spacer 210, and the ceramic substrate 100 ) and the first heat dissipation spacer 210 may be integrally bonded. The brazing temperature can be carried out at 450°C or higher. Ag, AgCu, and AgCuTi have high thermal conductivity, so they can increase bonding strength and facilitate heat transfer between the ceramic substrate 100 and the heat dissipation spacer 200, thereby increasing heat dissipation efficiency. The first bonding layer 10 may be formed by any one of plating, paste application, and foil attachment, and may have a thickness of about 0.005 mm to about 1.0 mm.

When the first bonding layer 10 is an Ag sintering bonding layer, silver sintering paste may be disposed between the upper metal layer 120 of the ceramic substrate 100 and the first heat dissipation spacer 210, and silver The ceramic substrate 100 and the first heat radiation spacer 210 may be bonded by sintering the sintering paste at a low temperature of about 200°C. This Ag Sintering joint has high temperature stability as the melting point of the sintered body rises to 700℃ or more after joining, and the joint strength is excellent at about 80 MPa.

Meanwhile, the ceramic substrate 100 and the first heat dissipation spacer 200 may be bonded by brazing after being temporarily bonded through thermochemical bonding. In this case, the thermochemical bonding may be bonding using thermal fusion, an adhesive, an adhesive, or the like. As described above, the ceramic substrate 100 and the first heat dissipation spacer 200 are airtightly bonded to each other by a bonding method such as brazing bonding or Ag sintering bonding, so that bonding strength is high and high-temperature reliability is excellent.

6 is a conceptual diagram illustrating a configuration in which a ceramic substrate unit according to an embodiment of the present invention is mounted on a refrigerant circulation unit and a circulation driving unit is connected to the refrigerant circulation unit.

As shown in FIG. 6, the heat sink 300 is bonded to the lower metal layer 130 of the ceramic substrate 100, and is made of any one of Cu, Al, and Cu alloys having high thermal conductivity for heat dissipation. can The heat sink 300 may include a flat portion 310 and a plurality of protrusions 320 . As will be described later, the plurality of protrusions 320 may form passages through which liquid refrigerant flows. The heat sink 300 may be a heat sink such as a Micro Channel, Pin Fin, Micro Jet, Slit, or pipe type. ) will be explained.

The planar portion 310 may be formed in a flat plate shape so that the upper surface directly contacts the lower metal layer 130 and increases the bonding force by maximizing the bonding area with the lower metal layer 130 . The plurality of protrusions 320 may be spaced apart from each other on the lower surface of the flat portion 310 and form a passage through which liquid refrigerant flows. In this embodiment, a slit-type heat sink in which a plurality of rod-shaped protrusions 320 are horizontally arranged at intervals from each other is shown, but is not limited thereto, and the plurality of protrusions 320 may be cylinders, polygonal columns, or teardrops. It may be provided in various pin shapes such as a drop shape and a diamond shape. The shape of the protrusion 320 may be implemented by mold processing, etching processing, milling processing, or other processing.

A plurality of protrusions 320 may be disposed in the refrigerant circulation unit 2 . The refrigerant circulation unit 2 may include an inlet 2a through which the liquid refrigerant flows, an outlet 2b through which the 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 introduced through the inlet 2a of the refrigerant circulation unit 2 may be discharged through the outlet 2b through the internal passage. Since the shape and size of the inner passage, which is the path through which the liquid refrigerant moves between the inlet (2a) and the outlet (2b), can be variously designed, a detailed description of the inner passage itself of the refrigerant circulation unit (2) will be omitted. do it with

The circulation driving unit 3 is connected to the refrigerant circulation unit 2 and may circulate the liquid refrigerant by using a driving force of a pump (not shown). Here, the inlet 2a of the refrigerant circulation unit 2 may be connected to the circulation driving 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 ( It may be connected to the circulation driving unit 3 through L2). That is, the circulation driving unit 3 may 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 necessary.

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 to the circulation drive unit 3 again through the second circulation line (L2). Although not shown in detail, the circulation driver 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 passage of the refrigerant circulation unit 2, and the circulation drive unit 3 transfers the liquid refrigerant whose temperature has been lowered by the heat exchanger to the pump. It can be supplied to the first circulation line (L1) again by using the driving force.

In this way, the refrigerant circulation unit 2 may be provided so that the liquid refrigerant supplied from the circulation driving unit 3 continuously circulates. At this time, the plurality of protrusions 320 are disposed in the inner flow path of the refrigerant circulation unit 2 and can directly contact and exchange heat with the liquid refrigerant continuously circulating along the inner flow path. That is, the plurality of protrusions 320 have a water-cooled heat dissipation structure that can be directly cooled by a continuously circulating liquid refrigerant.

The plurality of protrusions 320 are forcibly cooled by the continuously circulating liquid refrigerant even when high-temperature heat is generated from the semiconductor chip c, etc., thereby preventing overheating of the ceramic substrate 100 and preventing the semiconductor chip c from deteriorating. It can be maintained at a constant temperature so that it does not. That is, even if high-temperature heat of about 100° C. or more is generated in the semiconductor chip (c), the temperature of the liquid refrigerant circulating along the internal flow path of the refrigerant circulation unit 2 is about 25° C. Heat can be quickly cooled.

Conventionally, a base plate for heat dissipation is soldered to a ceramic substrate. In the case of soldering paste such as Ag epoxy used at this time, the thermal conductivity is as low as about 110 W/m K, so the cooling efficiency is low, and TIM such as graphite ( Thermal Interface Materials) There is a problem in that the manufacturing process is complicated because the process of coating the material must be additionally performed.

On the other hand, in the present invention, the heat sink 300 having the flat portion 310 and the plurality of protrusions 320 is brazed to the ceramic substrate 100, and materials such as Ag, AgCu, and AgCuTi used for brazing are Since the thermal conductivity is about 350 W/m K or more, the thermal conductivity is about 3 times higher than that of the prior art, so the heat dissipation effect can be maximized. In addition, compared to the prior art, the process can be simplified and energy and cost can be saved.

In addition, the ceramic substrate unit 1 according to the embodiment of the present invention is a structure in which the heat sink 300 and the ceramic substrate 100 are integrated, and the heat generated from the semiconductor chip C can be directly cooled. Therefore, it is possible to increase heat dissipation performance while realizing light weight and miniaturization.

In addition, since the ceramic substrate unit 1 according to the embodiment of the present invention has a water-cooled heat dissipation structure, it can rapidly absorb and dissipate heat by varying the flow rate of the liquid refrigerant, thereby increasing the heat dissipation effect compared to the conventional air-cooled heat dissipation structure. can be maximized.

The shape, number, and arrangement of the plurality of protrusions 320 can be changed in various ways according to a preliminary simulation result during design. Since the liquid refrigerant flows between the plurality of protrusions 320, the flow rate, flow rate, and cooling efficiency of the liquid refrigerant can be easily controlled by changing the shape, number, and arrangement of the plurality of protrusions 320.

The ceramic substrate 100 and the heat sink 300 may be bonded to each other by the second bonding layer 20 . In this case, the second bonding layer 20 may be a brazing bonding layer or an Ag sintering bonding layer made of a material including at least one of Ag, Cu, AgCu, and AgCuTi. When the second bonding layer 20 is a brazing bonding layer, the second bonding layer 20 may be disposed between the lower metal layer 130 of the ceramic substrate 100 and the planar portion 310 of the heat sink 300, , the ceramic substrate 100 and the heat sink 300 may be integrally bonded at a brazing temperature. The brazing temperature can be carried out at 450°C or higher. Ag, AgCu, and AgCuTi have high thermal conductivity, so they can increase bonding strength and facilitate heat transfer between the ceramic substrate 100 and the heat sink 300, thereby increasing heat dissipation efficiency. The second bonding layer 20 may be formed by any one of plating, paste application, and foil attachment, and may have a thickness of about 0.005 mm to about 1.0 mm.

When the second bonding layer 20 is an Ag sintering bonding layer, the silver sintering paste is disposed between the lower metal layer 130 of the ceramic substrate 100 and the planar portion 310 of the heat sink 300. The ceramic substrate 100 and the heat sink 300 may be bonded by sintering the silver sintering paste at a low temperature of about 200° C. This Ag Sintering joint has high temperature stability as the melting point of the sintered body rises to 700℃ or more after joining, and the joint strength is excellent at about 80 MPa.

Meanwhile, the ceramic substrate 100 and the heat sink 300 may be bonded by brazing after being temporarily bonded through thermochemical bonding. In this case, the thermochemical bonding may be bonding using thermal fusion, an adhesive, an adhesive, or the like. As described above, the ceramic substrate 100 and the heat sink 300 may be airtightly bonded to each other by a bonding method such as brazing bonding or Ag sintering bonding, and may have high bonding strength capable of withstanding water pressure, hydraulic pressure, and the like.

7 is a flowchart illustrating a method of manufacturing a ceramic substrate unit according to an embodiment of the present invention.

As shown in FIG. 7 , the ceramic substrate manufacturing method according to an embodiment of the present invention includes preparing a ceramic substrate 100 having metal layers 120 and 130 on upper and lower surfaces of a ceramic substrate 110 (S10), and a semiconductor semiconductor substrate 100 . Preparing a heat dissipation spacer 200 equipped with an electrode 211b for bonding the chip (c) in the form of a flip chip (S20); A bonding step (S30) and a bonding step (S40) of the heat sink 300 to the lower metal layer 130 of the ceramic substrate 100 may be included. Here, each step may be performed sequentially, may be performed in reverse order with each other, or may be performed substantially simultaneously.

In the step of preparing the ceramic substrate 100 ( S10 ), the ceramic substrate 100 may be any one of an active metal brazing (AMB) substrate, a direct bonded copper (DBC) substrate, and a thick printing copper (TPC) substrate. Here, the ceramic substrate 100 is provided with a ceramic substrate 110 and an upper metal layer 120 and a lower metal layer 130 on the upper and lower surfaces of the ceramic substrate 110 to increase heat dissipation efficiency of the heat generated from the semiconductor chip. can

In the step of preparing the heat dissipation spacer 200 (S20), the heat dissipation spacer 200 has a shape corresponding to the upper metal layer 120 of the ceramic substrate 100, and the lower surface is bonded to the upper metal layer 120, and the electrode ( 211b) and at least one disposed at a position facing one end of the first heat dissipation spacer 210 having the wiring part 211 including the electrode 211b, and to which the electrode of the semiconductor chip c is bonded to the upper surface. It may include a second heat dissipation spacer 220 of.

Here, the wiring part 211 of the first heat dissipation spacer 210 may include an insulating layer 211a and an electrode 211b. Specifically, the insulating layer 211a may be disposed in the groove h formed on the first heat dissipation spacer 210 and made of an insulating material. For example, PI (Polyimide), FR4, Ceramic (Alumina, ZTA, AlN, Si ₃ N ₄ , etc.) may be used as the insulating layer, but is not limited thereto. The electrode 211b may be disposed on the insulating layer 211a. Here, the electrodes 211b may be arranged to be inserted to a certain depth in the upper surface of the insulating layer 211a, and may be provided as a pair and spaced apart in the width direction of the insulating layer 211a.

The electrode 211b may extend along the groove h of the first heat dissipation spacer 210 from one end disposed at a position facing the second heat dissipation spacer 220 to form a wire. That is, since one end of the electrode 211b is disposed at a position facing the second heat dissipation spacer 220, the electrode 211b is connected to the semiconductor chip c bonded to the second heat dissipation spacer 220 to serve as an electric line for transmitting an electric signal. can do. For example, Cu, Ag, Ni-Au, W, Mo, MoW, etc. may be used as the electrode, but is not limited thereto.

Bonding the heat dissipation spacer 200 to the upper metal layer 120 of the ceramic substrate 100 (S20) includes a first bonding disposed between the upper metal layer 120 of the ceramic substrate 100 and the heat dissipation spacer 200. The heat dissipation spacer 200 is bonded to the upper metal layer 120 via the layer 10, and the first bonding layer 10 is made of a material including at least one of Ag, Cu, AgCu, and AgCuTi, or Ag sintered. It may consist of a paste. When the first bonding layer 10 is a brazing bonding layer made of a material including at least one of Ag, Cu, AgCu, and AgCuTi, the brazing bonding layer is formed between the upper metal layer 120 of the ceramic substrate 100 and the first heat dissipation spacer ( 210), and the ceramic substrate 100 and the first heat dissipation spacer 210 may be integrally bonded at a brazing temperature. The brazing temperature can be carried out at 450°C or higher. The first bonding layer 10 may be formed by any one of plating, paste application, and foil attachment, and may have a thickness of about 0.005 mm to about 1.0 mm.

When the first bonding layer 10 is an Ag sintering bonding layer, silver sintering paste may be disposed between the upper metal layer 120 of the ceramic substrate 100 and the first heat dissipation spacer 210, and silver The ceramic substrate 100 and the first heat radiation spacer 210 may be bonded by sintering the sintering paste at a low temperature of about 200°C. This Ag Sintering joint has high temperature stability as the melting point of the sintered body rises to more than 700℃ after joining, and the joint strength is excellent at about 80 MPa.

In the step of bonding the heat sink 300 to the lower metal layer 130 of the ceramic substrate 100 (S30), the heat sink 300 is made of a material such as Cu, Al, or Cu alloy having high thermal conductivity for heat dissipation. A flat portion 310 and a plurality of protrusions 320 may be provided. The flat portion 310 is a portion in direct contact with the lower metal layer 130 on its upper surface, and may be provided in a flat plate shape to maximize the bonding area. The plurality of protrusions 320 may be disposed at intervals from each other on the lower surface of the flat portion 310 . The plurality of protrusions 320 may be disposed in the external refrigerant circulation unit 2 (see FIG. 6 ) to directly contact the liquid refrigerant circulating through the refrigerant circulation unit 2 .

Although the present embodiment shows a slit-type heat sink 300 in which a plurality of bar-shaped protrusions 320 are horizontally arranged at intervals from each other, the present embodiment is not limited thereto, and the plurality of protrusions 320 are cylindrical, It may be provided in various pin shapes such as prism, teardrop shape, and diamond shape. The shape of the protrusion 320 may be implemented by mold processing, etching processing, milling processing, or other processing. In this embodiment, an example in which a plurality of protrusions 320 are provided in the step of bonding the heat sink 300 to the lower metal layer 130 of the ceramic substrate 100 (S30) is described, but the plurality of protrusions 320 may be formed after the bonding step (S30). For example, after preparing a heat sink 300 in the form of a thick flat plate and bonding it to the lower metal layer 130 of the ceramic substrate 100, a plurality of protrusions 320 are formed by removing a portion thereof by etching or milling. can also be formed.

Bonding the heat sink 300 to the lower metal layer 130 of the ceramic substrate 100 (S30) is between the lower metal layer 130 of the ceramic substrate 100 and the planar portion 310 of the heat sink 300. The heat sink 300 is bonded to the lower metal layer 130 via the second bonding layer 20 disposed thereon, and the second bonding layer 20 is a material containing at least one of Ag, Cu, AgCu, and AgCuTi. or Ag sintering paste. When the second bonding layer 20 is a brazing bonding layer made of a material including at least one of Ag, Cu, AgCu, and AgCuTi, the second bonding layer 20 is formed by heat bonding with the lower metal layer 130 of the ceramic substrate 100. It may be disposed between the flat portion 310 of the sink 300, and the ceramic substrate 100 and the heat sink 300 may be integrally bonded at a brazing temperature. The brazing temperature can be carried out at 450°C or higher. The second bonding layer 20 may be formed by any one of plating, paste application, and foil attachment, and may have a thickness of about 0.005 mm to about 1.0 mm.

When the second bonding layer 20 is an Ag sintering bonding layer, the silver sintering paste is disposed between the lower metal layer 130 of the ceramic substrate 100 and the planar portion 310 of the heat sink 300. The ceramic substrate 100 and the heat sink 300 may be bonded by sintering the silver sintering paste at a low temperature of about 200° C. This Ag Sintering joint has high temperature stability as the melting point of the sintered body rises to more than 700℃ after joining, and the joint strength is excellent at about 80 MPa.

The above-described ceramic substrate unit of the present invention can be applied to a power module to secure both multi-volume connection and heat dissipation effects of semiconductor chips, and contribute to miniaturization, so that the performance of the power module can be further improved.

The ceramic substrate unit of the present invention described above is applicable to various module parts used for high power in addition to power modules.

The above description is merely an example of the technical idea of the present invention, and various modifications and variations can be made to those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed according to the claims below, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

1: ceramic substrate unit 2: refrigerant circulation unit
2a: inlet 2b: outlet
3: circulation driving unit L1: first circulation line
L2: second circulation line 10: first bonding layer
20: second bonding layer 100: ceramic substrate
110: ceramic substrate 120: upper metal layer
130: lower metal layer 200: heat dissipation spacer
210: first heat dissipation spacer 211: wiring part
211a: insulating layer 211b: electrode
220: second heat dissipation spacer 300: heat sink
310: flat part 320: protrusion

Claims (19)

A ceramic substrate having metal layers on upper and lower surfaces of the ceramic substrate;
a heat dissipation spacer bonded to the upper metal layer of the ceramic substrate; and
A heat sink bonded to a lower metal layer of the ceramic substrate,
The ceramic substrate unit of claim 1 , wherein the heat dissipation spacer has an electrode provided in a region where semiconductor chips are bonded to each other so that the semiconductor chips are bonded in a flip chip form. According to claim 1,
The heat dissipation spacer is a ceramic substrate unit to which at least two semiconductor chips are bonded. According to claim 1,
The heat dissipation spacer,
a first heat dissipation spacer having a shape corresponding to the upper metal layer, a lower surface bonded to the upper metal layer, and a wiring unit including the electrode; and
and at least one second heat dissipation spacer disposed at a position facing one end of the electrode and having an upper surface thereof bonded to an electrode of the semiconductor chip. According to claim 3,
The wiring part,
an insulating layer disposed in a groove formed on an upper portion of the first heat dissipation spacer and formed of an insulating material; and
and an electrode disposed on the insulating layer and extending from the one end along the groove to form a wiring. According to claim 4,
the electrode,
Ceramic substrate units disposed to be inserted into the upper surface of the insulating layer at a predetermined depth, provided as a pair and spaced apart in the width direction of the insulating layer. According to claim 1,
The heat sink is
a flat part having an upper surface in contact with the lower metal layer; and
A ceramic substrate unit having a plurality of protrusions disposed on the lower surface of the flat part at intervals from each other and forming a passage through which a liquid refrigerant flows. According to claim 6,
The plurality of protrusions are disposed in an external refrigerant circulation unit,
The liquid refrigerant circulating through the refrigerant circulation part exchanges heat with the plurality of protrusions. According to claim 6,
The plurality of protrusions are provided in a bar shape and are horizontally arranged at intervals from each other. According to claim 6,
The plurality of protrusions are provided in a pin shape of at least one of a cylindrical shape, a polygonal column shape, a teardrop shape, and a diamond shape. According to claim 1,
The material of the heat sink is any one of Cu, Al, and Cu alloy ceramic substrate unit. According to claim 1,
The heat dissipation spacer,
A ceramic substrate unit made of a CPC material in which Cu or MoCu or Cu, CuMo, and Cu are sequentially stacked. According to claim 1,
Further comprising a first bonding layer disposed between the upper metal layer of the ceramic substrate and the heat dissipation spacer,
The first bonding layer is made of a material containing at least one of Ag, Cu, AgCu, and AgCuTi, or made of Ag sintering paste. According to claim 6,
Further comprising a second bonding layer disposed between the lower metal layer of the ceramic substrate and the planar portion of the heat sink,
The second bonding layer is made of a material containing at least one of Ag, Cu, AgCu, and AgCuTi, or made of Ag sintering paste. preparing a ceramic substrate having metal layers on upper and lower surfaces of the ceramic substrate;
preparing a heat dissipation spacer equipped with electrodes for bonding semiconductor chips in a flip chip form;
bonding the heat dissipation spacer to an upper metal layer of a ceramic substrate; and
A method of manufacturing a ceramic substrate unit comprising the step of bonding a heat sink to a lower metal layer of a ceramic substrate. According to claim 14,
In the step of preparing the heat dissipation spacer,
The heat dissipation spacer
a first heat dissipation spacer having a shape corresponding to the upper metal layer, a lower surface bonded to the upper metal layer, and a wiring unit including the electrode; and
and at least one second heat dissipation spacer disposed at a position facing one end of the electrode and having an upper surface thereof bonded to an electrode of the semiconductor chip. According to claim 15,
In the step of preparing the heat dissipation spacer,
The wiring part,
an insulating layer disposed in a groove formed on an upper portion of the first heat dissipation spacer and formed of an insulating material; and
and an electrode disposed on the insulating layer and extending from the one end along the groove to form a wire. According to claim 16,
In the step of preparing the heat dissipation spacer,
the electrode,
A method of manufacturing a ceramic substrate unit disposed to be inserted at a predetermined depth from an upper surface of the insulating layer and provided as a pair and spaced apart in a width direction of the insulating layer. According to claim 14,
Bonding the heat dissipation spacer to the upper metal layer of the ceramic substrate,
Bonding the heat dissipation spacer to the upper metal layer via a first bonding layer disposed between the upper metal layer and the heat dissipation spacer;
Wherein the first bonding layer is made of a material containing at least one of Ag, Cu, AgCu, and AgCuTi, or made of Ag sintering paste. According to claim 14,
Bonding the heat sink to the lower metal layer of the ceramic substrate,
Bonding the heat sink to the lower metal layer via a second bonding layer disposed between the lower metal layer and the planar portion of the heat sink;
The second bonding layer is made of a material containing at least one of Ag, Cu, AgCu, and AgCuTi, or made of Ag sintering paste.

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