Patent Description:
An insulated gate bipolar transistor (IGBT) is a composite full-controlled voltage-driven power semiconductor device including a bipolar transistor and an insulated gate field effect transistor, and is widely applied to various electronic devices. With the development of high-current electronic devices such as a converter, higher requirements are put forward on performance of an IGBT chip. The IGBT chip bears a higher current, and heat generated during operating of the IGBT chip continuously increases. Current direct packaging of the IGBT chip uses a vacuum welding technology. A packaging process totally includes three processes: manufacturing of an aluminum-clad ceramic heat conductor, processing on silicon carbide heat dissipation body, and welding between the aluminum-clad ceramic heat conductor and the silicon carbide heat dissipation body. The vacuum welding technology is complex and has a long production period. Moreover, bubbles generated in a welding process or an uneven solder layer may result in that voids having different shapes and sizes are formed at a welding layer. The voids in the welding layer may cause a current density effect, resulting in thermoelectric breakdown, poor heat conduction, and the like. Consequently, a packaging yield rate thereof decreases, and a service life is shortened.

<CIT> relates to a heat spreader module, a heat sink, and a manufacturing method thereof. <CIT> relates to an improvement of a semiconductor element module substrate, and more particularly, to improving the inter-layer compatibility in the respective laminated structures of a circuit board and a heat sink member, increasing the bonding strength, and improving the circuit strength. <CIT> relates to power semiconductors and particularly to a highly-reliable package for wide band gap power devices such as silicon carbide (SiC) power device applications and/or combined SiC and silicon power device applications. <CIT> relates to a heat spreader module for cooling an IC chip used in semiconductor devices or the like, and to a method of manufacturing such a heat spreader module.

Therefore, a new heat dissipation apparatus is urgently required to overcome the defects of vacuum welding in the prior art, to obtain a heat dissipation apparatus having a better heat conduction effect.

An objective of the present disclosure is to provide a heat dissipation element. The heat dissipation element has a good heat conduction effect, a simple structure, and a low processing difficulty.

To achieve the foregoing objective, the present disclosure provides a heat dissipation element. The heat dissipation element includes a heat conductor and a heat dissipation body; where the heat conductor is an aluminum-clad ceramic heat conductor; the heat dissipation body is an aluminum silicon carbon heat dissipation body; the aluminum silicon carbon heat dissipation body is provided with one or more grooves; and the aluminum-clad ceramic heat conductor is embedded into the groove through aluminizing in an integral forming manner. The aluminum-clad ceramic heat conductor comprises a ceramic insulating plate, and a first aluminum layer and a second aluminum layer that are integrally formed through aluminizing on two opposite surfaces of the ceramic insulating plate, and the first aluminum layer is adjacent to the aluminum silicon carbon heat dissipation body and is bonded to the aluminum silicon carbon heat dissipation body, wherein a thickness of the first aluminum layer is <NUM> to <NUM>, a thickness of the ceramic insulating plate is <NUM> to <NUM>, and a thickness of the second aluminum layer is <NUM> to <NUM>.

In the foregoing technical solution, compared with a heat dissipation element obtained through vacuum welding, the heat dissipation element described in the present disclosure has fewer voids at a metal layer, higher strength, and a higher yield rate, and a service life is extended; the heat dissipation element has a thinner aluminum layer, thereby improving heat conduction efficiency of the heat dissipation element; there is no gap on bonding surfaces between layers of the heat dissipation element provided in the present disclosure, thereby having higher connection strength and higher heat conduction efficiency; in addition, a relatively soft aluminum-clad ceramic cover layer provides the heat dissipation apparatus with more excellent performance in coldness and heat impact tolerance; moreover, the present disclosure uses the foregoing aluminum silicon carbon heat dissipation body provided with a groove, and the aluminum-clad ceramic heat conductor is embedded into the groove through aluminizing in an integral forming manner, thereby avoiding a case in which an edge of a pasted film cracks during etching to affect an etching pattern, improving accuracy of etching, and improving strength and stability of the heat dissipation element.

The present disclosure further provides a method for manufacturing a heat dissipation element. The method includes the following steps:.

Mount a silicon carbide porous skeleton and a ceramic insulating plate into an aluminizing mold, the silicon carbide porous skeleton being provided with at least one groove, the ceramic insulating plate being placed inside the groove, and enabling a first slot to exist between a groove bottom of the silicon carbide porous skeleton and the ceramic insulating plate, and a second slot to exist between the ceramic insulating plate and a wall of the aluminizing mold.

Under pressure casting infiltration conditions, add molten aluminum liquid into the preheated aluminizing mold, and filling the first slot, the second slot and the silicon carbide porous skeleton (<NUM>) with the molten aluminum liquid, perform operations of vacuum pumping and pressurizing, and then perform cooling and demolding.

Form an aluminum silicon carbon heat dissipation body after the interior of the silicon carbide porous skeleton is filled with aluminum, and remove a part of aluminum metal in the second slot by etching, to enable remaining aluminum metal in the second slot to form a second aluminum layer; and the second aluminum layer and a first aluminum layer being isolated by the ceramic insulating plate, and the second aluminum layer being isolated from the aluminum silicon carbon heat dissipation body, wherein a thickness of the first aluminum layer is <NUM> to <NUM>, a thickness of the ceramic insulating plate is <NUM> to <NUM>, and a thickness of the second aluminum layer is <NUM> to <NUM>.

In the foregoing technical solution, according to the method for manufacturing the heat dissipation element provided in the present disclosure, molten aluminum liquid or aluminum alloy liquid is integrally formed to produce an aluminum-clad ceramic heat conductor, and the aluminum-clad ceramic heat conductor is connected to a heat dissipation body. Three steps in a vacuum welding technology including manufacturing of the aluminum-clad ceramic heat conductor, processing on the heat dissipation body, and welding between the aluminum-clad ceramic heat conductor and the heat dissipation body are combined into one step, thereby shortening a production period of the heat dissipation element; moreover, the ceramic insulating plate is placed inside a groove of the aluminum silicon carbon heat dissipation body, so that it is easy to control a thickness of an aluminum layer on the surface of the aluminum-clad ceramic heat conductor, and the step simplifies the manufacturing process of the heat dissipation element.

The present disclosure further provides a heat dissipation element manufactured by using the foregoing method.

The present disclosure further provides an IGBT module. The IGBT module includes an IGBT circuit board and the heat dissipation element described above.

Other features and advantages of the present disclosure are described in detail in subsequent specific implementations.

The accompanying drawings are used to provide a further understanding of the present disclosure, and constitute a part of the specification. The accompanying drawings are used, along with the following specific implementations, to explain the present disclosure, but do not constitute any limitation on the present disclosure. In the drawings:.

The following describes specific implementations of the present disclosure in detail with reference to the accompanying drawings. It should be understood that the specific implementations described herein are merely used to describe and explain the present disclosure, but are not intended to limit the present disclosure.

A first aspect of the present disclosure provides a heat dissipation element. The heat dissipation element includes a heat conductor and a heat dissipation body, where the heat conductor is an aluminum-clad ceramic heat conductor; the heat dissipation body is an aluminum silicon carbon heat dissipation body <NUM>; the aluminum silicon carbon heat dissipation body <NUM> is provided with at least one groove <NUM>; and the aluminum-clad ceramic heat conductor is embedded into the groove <NUM> through aluminizing in an integral forming manner; wherein the heat conductor comprising a ceramic body and an aluminum layer disposed on the ceramic body.

According to the first aspect of the present disclosure, preferably, as shown in <FIG>, the aluminum-clad ceramic heat conductor includes a ceramic insulating plate <NUM>, and a first aluminum layer <NUM> and a second aluminum layer <NUM> that are integrally formed through aluminizing on two opposite surfaces of the ceramic insulating plate <NUM>, and the first aluminum layer <NUM> is adjacent to the aluminum silicon carbon heat dissipation body <NUM> and is bonded to the aluminum silicon carbon heat dissipation body <NUM>. In other words, the aluminum-clad ceramic heat conductor includes a ceramic insulating plate <NUM>, and a first aluminum layer <NUM> and a second aluminum layer <NUM> that are disposed on two opposite surfaces of the ceramic insulating plate <NUM>, and the ceramic insulating plate <NUM> is connected to the aluminum silicon carbon heat dissipation body <NUM> by using the first aluminum layer <NUM> that is integrally formed through aluminizing; the ceramic insulating plate <NUM> isolates the second aluminum layer <NUM> from the first aluminum layer <NUM>, and the second aluminum layer <NUM> is isolated from the aluminum silicon carbon heat dissipation body <NUM>; the first aluminum layer <NUM> connects the aluminum silicon carbon heat dissipation body <NUM> and the ceramic insulating plate <NUM> in an integral forming manner, so that there is no gap between the aluminum silicon carbon heat dissipation body <NUM> and the ceramic insulating plate <NUM>, thereby having better connection strength and extending a service life; and a circuit may be formed on the second aluminum layer <NUM> through etching.

According to the first aspect of the present disclosure, preferably, the ceramic insulating plate <NUM> is an aluminum oxide ceramic plate, a toughened aluminum oxide ceramic plate, an aluminum nitride ceramic plate, or a silicon nitride ceramic plate. An upper surface of the second aluminum layer <NUM> and an upper surface, except the groove <NUM>, of the aluminum silicon carbon heat dissipation body <NUM> form a flat surface. Ceramic plates made of the foregoing materials have relatively low density and relatively high hardness, thereby helping extend a service life. The formed flat surface is conducive to pasting a film during subsequent etching, and prevents the pasted film from cracking, and etching is performed according to a presetting to improve accuracy of etching.

According to the first aspect of the present disclosure, preferably, a thickness of the first aluminum layer <NUM> is <NUM> to <NUM>, a thickness of the ceramic insulating plate <NUM> is <NUM> to <NUM>, and a thickness of the second aluminum layer <NUM> is <NUM> to <NUM>; and the first aluminum layer <NUM> is selected from an aluminum layer or an aluminum alloy layer, the second aluminum layer <NUM> is selected from an aluminum layer or an aluminum alloy layer. The aluminum layer and the aluminum alloy layer can both satisfy heat conduction design of the heat dissipation apparatus, and the aluminum layer and the aluminum alloy layer have relatively low hardness and more excellent performance in coldness and heat impact tolerance. Therefore, use of the aluminum layer and the ceramic insulating plate <NUM> of the described thicknesses may improve efficiency and structural strength of the aluminum-clad ceramic heat conductor, and extend a service life.

According to the first aspect of the present disclosure, preferably, the aluminum silicon carbon heat dissipation body <NUM> is a silicon carbide porous skeleton <NUM> whose interior contains aluminum, where the aluminum is bonded to the interior of the silicon carbide porous skeleton <NUM> through aluminizing in an integral forming manner. In other words, the aluminum silicon carbon heat dissipation body <NUM> includes the silicon carbide porous skeleton <NUM> and the aluminum bonded to the interior of the silicon carbide porous skeleton <NUM> through aluminizing in an integral forming manner. The silicon carbide porous skeleton may integrally reinforce, along with the aluminum, structural strength of the aluminum silicon carbon heat dissipation body and connection strength of other components.

According to the first aspect of the present disclosure, preferably, as shown in <FIG>, the aluminum silicon carbon heat dissipation body <NUM> is further provided with at least one heat dissipation column <NUM> or one or more heat dissipation columns <NUM>; and one end of the heat dissipation column <NUM> is fixedly connected to the aluminum silicon carbon heat dissipation body <NUM>, and the other end of the heat dissipation column <NUM> is a free end. The heat dissipation column <NUM> is disposed on a surface, opposite to one side of the aluminum-clad ceramic heat conductor, of the aluminum silicon carbon heat dissipation body <NUM>. The heat dissipation column <NUM> can conduct heat radiated by an IGBT module, to improve heat dissipation efficiency.

According to the first aspect of the present disclosure, preferably, the heat dissipation column <NUM> is at least one of an aluminum column, an aluminum alloy column, and an aluminum-clad copper column; the heat dissipation column <NUM> is connected to the aluminum silicon carbon heat dissipation body <NUM> through aluminizing in an integral forming manner; and connection strength between the integrally formed heat dissipation column <NUM> and the aluminum silicon carbon heat dissipation body <NUM> is higher, thereby reinforcing strength of the heat dissipation apparatus and extending a service life of the heat dissipation apparatus.

According to the first aspect of the present disclosure, there are one groove <NUM> and one ceramic insulating plate <NUM> for one aluminum silicon carbon heat dissipation body <NUM>, and there are at least one first aluminum layer <NUM> and at least one second aluminum layer <NUM> for one aluminum silicon carbon heat dissipation body <NUM>;Or there are at least two grooves <NUM> for one aluminum silicon carbon heat dissipation body <NUM>, and a quantity of the first aluminum layers <NUM>, the second aluminum layers <NUM>, and the ceramic insulating plates <NUM> are each the same as the grooves <NUM>.

Relative to a same aluminum silicon carbon heat dissipation body <NUM>, one groove and one ceramic insulating plate are disposed, there is one first aluminum layer <NUM> and one or more second aluminum layers <NUM>, and the plurality of second aluminum layers <NUM> are spaced apart from each other; alternatively, there are a plurality of grooves, and quantities of first aluminum layers <NUM>, second aluminum layers <NUM>, and ceramic insulating plates <NUM> are the same as a quantity of the grooves <NUM>.

The foregoing different settings of the groove <NUM>, the ceramic insulating plate <NUM>, the first aluminum layer <NUM>, and the second aluminum layer <NUM> can satisfy different requirements for heat dissipation design.

A second aspect of the present disclosure provides a method for manufacturing a heat dissipation element. The method includes the following steps:.

In the foregoing technical solution, according to the method for manufacturing the heat dissipation element provided in the present disclosure, molten aluminum liquid or aluminum alloy liquid is integrally formed to produce an aluminum-clad ceramic heat conductor, and the aluminum-clad ceramic heat conductor is connected to an aluminum silicon carbon heat dissipation body <NUM>. Three steps in a vacuum welding technology including manufacturing of the aluminum-clad ceramic heat conductor, processing on the aluminum silicon carbon heat dissipation body, and welding between the aluminum-clad ceramic heat conductor and the aluminum silicon carbon heat dissipation body <NUM> are combined into one step, thereby shortening a production period of the heat dissipation element; moreover, the ceramic insulating plate <NUM> is placed inside a groove <NUM> of the aluminum silicon carbon heat dissipation body <NUM>, so that it is easy to control a thickness of an aluminum layer on the surface of the aluminum-clad ceramic heat conductor, and the step simplifies the manufacturing process of the heat dissipation element.

The operation of providing the silicon carbide porous skeleton <NUM> with one or more grooves <NUM> may be implemented by using computer numerical control (CNC) machine tools.

According to the second aspect of the present disclosure, preferably, the pressure casting infiltration conditions include: a temperature of the preheating is <NUM> to <NUM>, a temperature of the molten aluminum liquid is <NUM> to <NUM>, a pressure of the vacuum pumping is <NUM> to <NUM> Pa, a pressure of the pressurizing is <NUM> to <NUM> MPa, and the molten aluminum liquid is pure aluminum or aluminum alloy. Pressure aluminizing in an integral forming manner under the conditions can reduce voids in the first aluminum layer <NUM>, the second aluminum layer <NUM>, and a metal layer of the heat dissipation column <NUM>, thereby improving production quality and a yield rate.

According to the second aspect of the present disclosure, preferably, the silicon carbide porous skeleton <NUM> is mounted into the aluminizing mold <NUM>, and an upper surface, on which the groove <NUM> is formed, of the silicon carbide porous skeleton <NUM> is enabled to abut against an inner wall of the aluminizing mold <NUM>, so that an upper surface of the formed second aluminum layer <NUM> and an upper surface of the obtained aluminum silicon carbon heat dissipation body <NUM> form a flat surface. In other words, a wall of the aluminizing mold <NUM> enables the upper surface of the second aluminum layer <NUM> and the upper surface, except the groove <NUM>, of the aluminum silicon carbon heat dissipation body <NUM> to form a flat surface. The formed flat surface is conducive to pasting a film during subsequent etching, and prevents the pasted film from cracking, and etching is performed according to a presetting to improve the accuracy of etching.

According to the second aspect of the present disclosure, preferably, at least one column-shaped recess <NUM> protruding outward is formed on an inner surface of the aluminizing mold <NUM>, and the column-shaped recess <NUM> is suitable for forming at least one heat dissipation column <NUM> connected to the silicon carbide porous skeleton <NUM>. In other words, a third slot <NUM> further exists between the silicon carbide porous skeleton <NUM> and a wall of the aluminizing mold <NUM>. The third slot <NUM> is used to form the heat dissipation column <NUM>. The third slot may be comb-tooth-shaped, and the tooth-shaped protrusion is used to form the heat dissipation column. In the method, the heat dissipation column <NUM> may form connection with the aluminum silicon carbon heat dissipation body <NUM> in a one-time manner, thereby avoiding subsequent melding of the heat dissipation column <NUM>, and improving stability of the connection between the heat dissipation column <NUM> and the aluminum silicon carbon heat dissipation body <NUM>.

According to the second aspect of the present disclosure, preferably, the ceramic insulating plate <NUM> is an aluminum oxide ceramic plate, a toughened aluminum oxide ceramic plate, an aluminum nitride ceramic plate, or a silicon nitride ceramic plate; a thickness of the first aluminum layer <NUM> is <NUM> to <NUM>, a thickness of the ceramic insulating plate <NUM> is <NUM> to <NUM>, and a thickness of the second aluminum layer <NUM> is <NUM> to <NUM>. Ceramic plates made of the foregoing materials have relatively low density and relatively high hardness, thereby helping extend a service life. Use of the aluminum layers with the described thicknesses and the ceramic insulating plate <NUM> with the described thickness can improve heat conduction efficiency and structural strength of the aluminum-clad ceramic heat conductor, and extend the service life.

According to the second aspect of the present disclosure, wherein there are one groove <NUM> and one ceramic insulating plate <NUM> for one aluminum silicon carbon heat dissipation body <NUM> , and there are at least one first aluminum layer <NUM> and at least one second aluminum layer <NUM> for one aluminum silicon carbon heat dissipation body <NUM>;Or, there are at least two grooves <NUM> for one aluminum silicon carbon heat dissipation body <NUM> , and a quantity of the first aluminum layers <NUM>, the second aluminum layers <NUM>, and the ceramic insulating plates <NUM> are each the same as the grooves <NUM>.

Relative to a same aluminum silicon carbon heat dissipation body <NUM>, there may be one ceramic insulating plate <NUM> and one groove, there is one first aluminum layer <NUM> and one or more second aluminum layers <NUM>, and the plurality of second aluminum layers <NUM> are connected to the ceramic insulating plate <NUM> and are spaced apart from each other; alternatively, there are a plurality of grooves <NUM>, and quantities of first aluminum layers <NUM>, second aluminum layers <NUM>, and ceramic insulating plates <NUM> are the same as a quantity of the grooves.

According to the second aspect of the present disclosure, preferably, etching may be performed by using various methods generally used by a person skilled in the art. A parameter may be a generally used parameter. For example, an etching operation includes sequentially performed steps of pasting a film, exposing, developing, corroding, removing the film, and washing.

A third aspect of the present disclosure provides a heat dissipation element manufactured by using the foregoing method.

A fourth aspect of the present disclosure provides an IGBT module. The IGBT module includes an IGBT circuit board and the heat dissipation element described above.

The present disclosure is further described below by using embodiments, but the present disclosure is not limited thereto.

This embodiment is used to describe a method for manufacturing a heat dissipation element.

One silicon carbide porous skeleton <NUM> having a thickness of <NUM> and three aluminum oxide ceramic insulating plates <NUM> having a thickness of <NUM>, a length of <NUM>, and a width of <NUM> are mounted into an aluminizing mold <NUM>, where the silicon carbide porous skeleton <NUM> has a length of <NUM> and a width of <NUM>; and the silicon carbide porous skeleton <NUM> is provided with three grooves <NUM> having a depth of <NUM>, a length of <NUM>, and a width of <NUM> side by side by using computer numerical control (CNC) machine tools. An interval between each two consecutive grooves <NUM> is <NUM>. The ceramic insulating plate <NUM> is placed inside the groove <NUM>, to enable a first slot <NUM> having a thickness of <NUM> to exist between a groove bottom of the silicon carbide porous skeleton <NUM> and the ceramic insulating plate <NUM>, and a second slot <NUM> having a thickness of <NUM> to exist between the ceramic insulating plate <NUM> and a wall of the aluminizing mold <NUM>. A third slot <NUM> furthers exists between the wall of the aluminizing mold <NUM> and the silicon carbide porous skeleton <NUM>, and is used to form a heat dissipation column <NUM>. The third slot <NUM> is comb-tooth-shaped, and the tooth-shaped protrusion having a length of <NUM> is used to form the heat dissipation column <NUM>. An interval between each two consecutive tooth-shaped protrusions is <NUM>.

The aluminizing mold <NUM> is preheated to have a temperature of <NUM>. Molten aluminum liquid of <NUM> is added into the aluminizing mold <NUM>. Vacuum pumping is performed until a pressure inside the aluminizing mold <NUM> is <NUM> Pa, and then pressurizing is performed until the pressure is <NUM> MPa. After the aluminum liquid is cooled to be of a room temperature and shaped, demolding is performed. The silicon carbide porous skeleton <NUM> and the aluminum bonded to the interior of the silicon carbide porous skeleton <NUM> form an aluminum silicon carbon heat dissipation body <NUM>.

A part of aluminum metal in the first slot <NUM> and the second slot <NUM> is removed by etching after a film is pasted, so that remaining aluminum metal in the first slot <NUM> forms a first aluminum layer <NUM> having a thickness of <NUM>, and remaining aluminum metal in the second slot <NUM> forms a second aluminum layer <NUM> having a thickness of <NUM>. The ceramic insulating plate <NUM> isolates the second aluminum layer <NUM> from the first aluminum layer <NUM>, and the second aluminum layer <NUM> is isolated from the aluminum silicon carbon heat dissipation body <NUM>. A slot of <NUM> exists between the second aluminum layer <NUM> and an edge of the groove <NUM>.

The heat dissipation element described in this embodiment is obtained after etching is completed.

One silicon carbide porous skeleton <NUM> having a thickness of <NUM> and two toughened aluminum oxide ceramic insulating plates <NUM> having a thickness of <NUM>, a length of <NUM>, and a width of <NUM> are mounted into an aluminizing mold <NUM>, where the silicon carbide porous skeleton <NUM> has a length of <NUM> and a width of <NUM>; and the silicon carbide porous skeleton <NUM> is provided with two grooves <NUM> having a depth of <NUM>, a length of <NUM>, and a width of <NUM> side by side by using computer numerical control (CNC) machine tools. An interval between each two consecutive grooves <NUM> is <NUM>. The ceramic insulating plate <NUM> is placed inside the groove <NUM>, to enable a first slot <NUM> of <NUM> to exist between a groove bottom of the silicon carbide porous skeleton <NUM> and the ceramic insulating plate <NUM>, and a second slot <NUM> of <NUM> to exist between the ceramic insulating plate <NUM> and a wall of the aluminizing mold <NUM>. A third slot <NUM> furthers exists between the wall of the aluminizing mold <NUM> and the silicon carbide porous skeleton <NUM>, and is used to form a heat dissipation column <NUM>. The third slot <NUM> is comb-tooth-shaped, and the tooth-shaped protrusion having a length of <NUM> is used to form the heat dissipation column <NUM>. An interval between each two consecutive tooth-shaped protrusions is <NUM>.

One silicon carbide porous skeleton <NUM> having a thickness of <NUM> and one aluminum nitride ceramic insulating plate <NUM> having a thickness of <NUM>, a length of <NUM>, and a width of <NUM> are mounted into an aluminizing mold <NUM>, where the silicon carbide porous skeleton <NUM> has a length of <NUM> and a width of <NUM>; and the silicon carbide porous skeleton <NUM> is provided with one groove <NUM> having a depth of <NUM>, a length of <NUM>, and a width of <NUM> by using computer numerical control (CNC) machine tools. The ceramic insulating plate <NUM> is placed inside the groove <NUM>, to enable a first slot <NUM> of <NUM> to exist between a groove bottom of the silicon carbide porous skeleton <NUM> and the ceramic insulating plate <NUM>, and a second slot <NUM> of <NUM> to exist between the ceramic insulating plate <NUM> and a wall of the aluminizing mold <NUM>. A third slot <NUM> furthers exists between the wall of the aluminizing mold <NUM> and the silicon carbide porous skeleton <NUM>, and is used to form a heat dissipation column <NUM>. The third slot <NUM> is comb-tooth-shaped, and the tooth-shaped protrusion having a length of <NUM> is used to form the heat dissipation column <NUM>. An interval between each two consecutive tooth-shaped protrusions is <NUM>.

A part of aluminum metal in the first slot <NUM> and the second slot <NUM> is removed by etching after a film is pasted, so that remaining aluminum metal in the first slot <NUM> forms a first aluminum layer <NUM> having a thickness of <NUM>, and remaining aluminum metal in the second slot <NUM> forms three second aluminum layers <NUM> having a thickness of <NUM>, a length of <NUM>, and a width of <NUM>. There is an interval of <NUM> between the second aluminum layers <NUM>. The ceramic insulating plate <NUM> isolates the second aluminum layer <NUM> from the first aluminum layer <NUM>, and the second aluminum layer <NUM> is isolated from the aluminum silicon carbon heat dissipation body <NUM>. A slot of <NUM> exists between the second aluminum layer <NUM> and an edge of the groove <NUM>.

Silicon carbide particles and aluminum powder are mixed up and then are subject to cold press molding, hot pressing, annealing, and heat preservation to manufacture an aluminum silicon carbon heat dissipation body.

A ceramic-coated copper heat conductor is preheated at a temperature of <NUM> in hydrogen by using a solder of SnPbAg, and is welded to the aluminum silicon carbon heat dissipation body at a temperature of <NUM> to manufacture a heat dissipation element of this comparative example. The ceramic-coated copper heat conductor includes an aluminum oxide ceramic insulating plate having a thickness of <NUM>, a first copper sheet having a thickness of <NUM>, and a second copper sheet having a thickness of <NUM>. The first copper sheet and the second copper sheet are oxidatively welded on two opposite surfaces of the ceramic insulating plate.

A heat-cold cycling test is performed on heat dissipation elements obtained in Embodiments <NUM> to <NUM> and Comparative Example <NUM>.

The obtained heat dissipation elements are put into an ice-water mixture. After <NUM> minutes, the heat dissipation elements are taken out from the ice-water mixture (continuously adding ice cubes and keeping a <NUM> environment). After being placed under a room temperature for <NUM> minutes, the heat dissipation elements are put into an oven of <NUM>. After being kept in <NUM> for <NUM> minutes, the heat dissipation elements are taken out from the oven. After being placed at a room temperature for <NUM> minutes, the heat dissipation elements are put into the ice-water mixture (continuously adding ice cubes and keeping a <NUM> environment) again by using a heat dissipation bottom plate. The foregoing process is a cycle. <NUM> heat dissipation elements in each group are separately subject to a performance measurement in coldness and heat impact tolerance. For every <NUM> cycles, a status (an appearance inspection, for example, a crack and a falling-off situation) of an aluminum layer of a to-be-measured sample is observed once. When the aluminum layer of the to-be-measured sample has an obvious crack and a falling-off tendency, the test for the to-be-measured sample is stopped. A quantity of times for which the to-be-measured sample has gone through the foregoing cycle so far is recorded, and an average of quantities of times for which the <NUM> to-be-measured heat dissipation elements in each group have gone through the cycle in the test is calculated. Measurement results of the foregoing heat dissipation elements of each group are shown in Table <NUM>.

Claim 1:
A heat dissipation element, comprising a heat conductor and a heat dissipation body, wherein the heat conductor is an aluminum-clad ceramic heat conductor; the heat dissipation body is an aluminum silicon carbon heat dissipation body (<NUM>); the aluminum silicon carbon heat dissipation body (<NUM>) is provided with at least one groove (<NUM>); and the aluminum-clad ceramic heat conductor is embedded into the groove (<NUM>) through aluminizing in an integral forming manner; wherein
the aluminum-clad ceramic heat conductor comprises a ceramic insulating plate (<NUM>), and a first aluminum layer (<NUM>) and a second aluminum layer (<NUM>) that are integrally formed through aluminizing on two opposite surfaces of the ceramic insulating plate (<NUM>), and the first aluminum layer (<NUM>) is adjacent to the aluminum silicon carbon heat dissipation body (<NUM>) and is bonded to the aluminum silicon carbon heat dissipation body (<NUM>), wherein a thickness of the first aluminum layer (<NUM>) is <NUM> to <NUM>, a thickness of the ceramic insulating plate (<NUM>) is <NUM> to <NUM>, and a thickness of the second aluminum layer (<NUM>) is <NUM> to <NUM>.