CN211614560U - Die for welding IGBT module - Google Patents

Abstract

The utility model provides a mould is used in welding of IGBT module belongs to electronic packaging equipment technical field. It has solved the inhomogeneous problem of current copper bottom plate being heated. This mould is used in welding of IGBT module, the package includes the hot plate the upper surface of hot plate is provided with the heat conduction piece, the coefficient of heat conductivity of heat conduction piece is less than the coefficient of heat conductivity of hot plate. The structure ensures that the lower surface of the copper base plate is uniformly heated integrally, the conditions of local overheating and overhigh temperature are avoided, the copper base plate is not deformed in the welding process of the DBC plate and the copper base plate, the copper base plate can be fully contacted with a radiator, and the radiating efficiency of the IGBT module is improved; the structure of the die is simpler, and the die is more convenient to manufacture.

Description

Die for welding IGBT module

Technical Field

The utility model belongs to the technical field of the electronic packaging equipment, a mould is related to, especially a mould is used in welding of IGBT module.

Background

The IGBT module is a common semiconductor device, and the IGBT module includes copper base plate and DBC board, and the DBC board passes through the solder welding and on the upper surface of copper base plate, during the welding, at first places the copper base plate at the upper surface of hot plate for the copper base plate contacts with the hot plate, and on the hot plate heat conduction to the copper base plate after generating heat, along with the temperature rising of copper base plate, the solder between DBC board and the copper base plate upper surface melts, makes the upper surface welded fastening of DBC board and copper base plate. The DBC board is the copper-clad plate of pottery, and copper bottom plate and the great difference of ceramic copper-clad plate thermal expansion coefficient are through large tracts of land high temperature welding back, and the bottom plate can take place to warp, leads to with radiator contact failure, and the bottom plate carries out the preflex of certain radian before the welding, still has certain camber after the copper bottom plate through the preflex carries out packaging technology and handles, guarantees that the contact is abundant between bottom plate and the radiator, is favorable to the module heat dissipation.

Because the whole copper bottom plate has a certain radian, the lower surface of the copper bottom plate is an arc-shaped curved surface, and the upper surface of the heating plate is a plane, so that the lower surface of the copper bottom plate cannot be completely attached to the upper surface of the heating plate, and the middle part of the lower surface of the copper bottom plate is the lowest part of the arc-shaped curved surface, therefore, the middle part of the lower surface of the copper bottom plate is contacted with the upper surface of the heating plate, the heat of the heating plate is directly transferred to the middle part of the copper bottom plate and is diffused from the middle part to the periphery of the copper bottom plate, the temperature of the middle part of the copper bottom plate is higher due to the heat transfer mode, the temperature of the periphery of the copper bottom plate is lower, when the temperature of the periphery of the copper bottom plate is raised to be capable of melting the solder between the DBC plate and the copper bottom plate, because the copper bottom plate is heated unevenly, the DBC plate located in the middle of the upper surface of the copper base plate can not be welded with the copper base plate, the middle of the copper base plate is overheated, and even a chip on the DBC plate can be damaged, and the heating mode needs to be heated for a long time to improve the temperature around the copper base plate, so that more energy is consumed.

In order to ensure the uniformity of the temperature of the copper base plate during the heating process, the chinese patent network discloses a method for welding a heating plate and an IGBT module [ application publication No.: CN104952813A, the back of IGBT module bottom plate is the arc curved surface, and the hot plate setting is at the back of bottom plate, and the hot plate includes the basement with be located the heating post array that a plurality of heating posts constitute on this basement, and single heating post possesses elasticity, and the upper surface of heating post array forms with bottom plate back matched with arc curved surface by the back extrusion of bottom plate when the welding. When the heating device is used, the IGBT module is placed on the heating plate through the tool, the bottom plate sinks under the action of gravity, the heating columns are pressed, the heating columns with elasticity are elastically deformed, the upper surfaces of the heating columns are completely attached to the back surface of the bottom plate, the bottom surface of the bottom plate is not completely covered due to the space between the heating columns, each heating column is used for locally heating the bottom surface of the bottom plate, although the heating uniformity of the bottom plate is improved to a certain degree, the bottom plate is uniformly heated, particularly the part of the bottom plate, which is directly contacted with the upper surfaces of the heating columns, has the conditions of overhigh temperature and overheating, so that the bottom plate is locally arched and deformed upwards, the bottom plate is poorly contacted with a radiator after the bottom plate is deformed, the heat dissipation efficiency of the IGBT module is reduced, and in addition, the chip on the DBC plate can be damaged due to overhigh local temperature; furthermore, due to the limitation of the process, the radian of the lower surface of each copper base plate is not completely the same, and certain errors exist, and in order to enable the upper surface of the heating column to be attached to the lower surface of the copper base plate, the upper surface of the heating column in the patent is designed into an arc concave surface, but in practical situation, the radian of the arc concave surface is difficult to be consistent with the radian of the lower surface of the copper bottom plate, and in addition, the radian of the lower surface of the copper bottom plate has certain error, the arc concave surface is more difficult to be attached to the lower surface of the copper bottom plate, therefore, in fact, the upper surface of the heating column is in point contact with the lower surface of the copper base plate, and the part of the copper base plate, which is in direct contact with the upper surface of the heating column, has the conditions of overhigh temperature and overheating, so that the part is arched upwards and deformed, the bottom plate is in poor contact with the radiator, the heat dissipation efficiency of the IGBT module is reduced, and even a chip on the DBC board can be damaged.

Disclosure of Invention

The utility model aims at having the above-mentioned problem to current technique, provided a mould is used in welding of IGBT module, the utility model aims to solve the technical problem that: how to make the heating of the copper soleplate more uniform.

The purpose of the utility model can be realized by the following technical proposal:

the utility model provides a mould is used in welding of IGBT module, includes the hot plate, its characterized in that, the upper surface of hot plate is provided with the heat conduction piece, the coefficient of heat conductivity of heat conduction piece is less than the coefficient of heat conductivity of hot plate.

The lower surface of the copper bottom plate in the IGBT module is an arc-shaped curved surface, so the middle part of the lower surface of the copper bottom plate is the lowest part of the arc-shaped curved surface, the middle part of the lower surface of the copper bottom plate is in contact with the upper surface of the heat conducting block, gaps are reserved between other parts of the lower surface of the copper bottom plate and the upper surface of the heating plate, then the heating plate is heated, the heat of the heating plate is transferred to the heat conducting block, the heat of the heat conducting block is transferred to the copper bottom plate, the heat is diffused from the middle part of the copper bottom plate to the periphery, the middle part of the lower surface of the copper bottom plate is in direct contact with the heat conducting block, the temperature. Because the coefficient of heat conductivity of heat conduction piece is less than the coefficient of heat conductivity of hot plate, in-process heating the hot plate, the temperature of hot plate is higher than the temperature of heat conduction piece, there is the clearance between other positions except that the middle part of copper bottom plate lower surface and the upper surface of hot plate, the hot plate passes through the heat radiation and heats other positions except that the middle part of copper bottom plate lower surface, make the same rapid heating up of other positions except that the middle part of copper bottom plate lower surface, and then make the lower surface of copper bottom plate wholly be heated evenly, avoid appearing local overheat and the too high condition of temperature, make DBC board and copper bottom plate welded in-process copper bottom plate not take place to warp, the copper bottom plate can fully contact with the radiator, improve the radiating efficiency of IGBT module. In addition, compared with the prior art, the structure of the die is simpler, and the die is more convenient to manufacture.

In the above mould for welding the IGBT module, the middle part of the upper surface of the heating plate is provided with a groove, and the heat conducting block is embedded into the groove. Through the arrangement of the structure, the heating plate and the heat conducting block are of a split structure, so that the heating plate is convenient to process and manufacture; in addition, because the radian of the lower surface of the copper bottom plate of different grade type is inequality, make the lower surface of the copper bottom plate of different grade type and the interval of the upper surface of hot plate different, the accessible is changed the heat conduction piece this moment, change the coefficient of heat conductivity of heat conduction piece, make the difference grow of coefficient of heat conductivity between heat conduction piece and the hot plate or diminish, and then the lower surface of copper bottom plate is heated evenly, copper bottom plate does not take place to warp when guaranteeing DBC board and copper bottom plate welded, consequently, this mould is applicable to the welding of the copper bottom plate of different grade type and DBC board.

In the above-mentioned die for welding the IGBT module, the grooves are arranged along the width direction of the heating plate, and the front and rear ends of the grooves are both open. Through the setting of this structure, during the heat conduction piece installation, the heat conduction piece can be followed recess one end and pushed into to the recess in, and when the heat conduction piece was dismantled, the recess can be released to the heat conduction piece, and the installation and the dismantlement of heat conduction piece are convenient.

In foretell mould for welding of IGBT module, the mould still includes the template that is located the hot plate top, the template can slide from top to bottom for the hot plate, be provided with a plurality of DBC board along length direction interval on the template and place the mouth. Through the setting of this structure, place the back on the hot plate when the copper bottom plate, place the template on the copper bottom plate after that, fix a position the copper bottom plate, DBC board accessible DBC board is placed the mouth and is put in proper order on the copper bottom plate, makes things convenient for putting of DBC board.

In foretell mould for welding of IGBT module, the opening has been seted up on the template, the opening is the rectangle form and arranges along the length direction of template, all have a plurality of boss on the relative both sides wall in the opening, a plurality of boss sets up along the length direction interval of template on corresponding lateral wall, the boss one-to-one on two lateral walls. Through the setting of this structure, at first set up a through-hole at the template, boss one-to-one on two lateral walls, two bosss that set up relatively form a set ofly and separate out a DBC board with the opening and place the mouth, and the DBC board is put into the DBC board and is placed the mouth after, and the boss is separated adjacent DBC board, and the DBC board offsets with the boss and leans on spacing the DBC board, is favorable to the stable welding of DBC board and copper bottom plate.

In the above-mentioned mould for welding of IGBT module, the upper surface of hot plate is fixed with two at least reference columns, seted up two at least through-holes on the template, the through-hole corresponds with the reference column one-to-one, the reference column passes the through-hole. Through the arrangement of the structure, the through hole and the positioning column are matched so that the template can slide up and down along the positioning column.

In the above mold for welding the IGBT module, the mold further comprises a positioning plate located above the template, the positioning plate is provided with at least two sliding holes, the sliding holes correspond to the positioning columns one by one, and the positioning columns penetrate through the sliding holes; a plurality of observation ports are formed in the positioning plate, and the observation ports correspond to the DBC plate placing ports one to one. Through the setting of this structure, the locating plate is pressed in the template, to the further location that compresses tightly of copper bottom plate, avoids the copper bottom plate to take place to reciprocate, and the welding situation of copper bottom plate and DBC board can also be observed in the setting of viewing aperture, can also improve the radiating effect of copper bottom plate and DBC board for copper bottom plate and DBC board welding back quick fixation can also avoid the too high chip on to the DBC board of DBC board temperature to cause the damage.

In the die for welding the IGBT module, a separating strip is arranged between adjacent observation ports, and the separating strip is provided with a separating column capable of sliding along the vertical direction. Through the setting of this structure, the DBC board is placed and is placed mouthful back in the DBC board, and the insulated column moves down makes the lower extreme and the copper bottom plate of insulated column to support against, and the insulated column further keeps apart two adjacent DBC boards.

In the above-mentioned mold for welding an IGBT module, the lower surface of the positioning plate has a support table, and the support table can abut against the upper surface of the template. Through the setting of this structure, the upper surface of brace table and template offsets and leans on the back, and the lower surface of locating plate is gapped with the upper surface of template, just can outwards spill through the clearance at the heat that welding process produced like this, realizes the effective heat dissipation in the welding process, avoids the too high chip on to the DBC board of DBC board temperature to cause the damage.

In the above-mentioned mold for welding an IGBT module, the heating plate is made of an aluminum material, and the heat conduction block is made of a graphite material.

Compared with the prior art, the utility model discloses a mould for welding of IGBT module has following advantage: the structure ensures that the lower surface of the copper base plate is uniformly heated integrally, the conditions of local overheating and overhigh temperature are avoided, the copper base plate is not deformed in the welding process of the DBC plate and the copper base plate, the copper base plate can be fully contacted with a radiator, and the radiating efficiency of the IGBT module is improved; the structure of the die is simpler, and the die is more convenient to manufacture.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is an explosion structure diagram of the heating plate and the copper bottom plate of the present invention.

Fig. 3 is a schematic sectional structure of the present invention.

Fig. 4 is a schematic perspective view of the heating plate, the copper bottom plate and the mold plate of the present invention.

In the figure, 1, a heating plate; a groove 1 a; 2. a template; 21. a port; 21a, a DBC plate placing opening; 22. a boss; 23. a through hole; 3. a positioning column; 4. positioning a plate; 41. a slide hole; 42. a viewing port; 43. a dividing strip; 44. a support table; 5. an isolation column; 6. a heat conducting block; 7. a copper base plate; 71. and (7) installing holes.

Detailed Description

The following are specific embodiments of the present invention and the accompanying drawings are used to further describe the technical solution of the present invention, but the present invention is not limited to these embodiments.

Example 1

As shown in fig. 1 and 4, the mold for welding the IGBT module includes a heating plate 1, a template 2 and a positioning plate 4, wherein a heat conducting block 6 is disposed on an upper surface of the heating plate 1, a groove 1a is formed in a middle portion of the upper surface of the heating plate 1, the heat conducting block 6 is embedded into the groove 1a, an upper surface of the heat conducting block 6 is flush with the upper surface of the heating plate 1, and a heat conductivity coefficient of the heat conducting block 6 is smaller than that of the heating plate 1, in this embodiment, the heating plate 1 is made of an aluminum material, and the heat conducting block 6 is made of a graphite material; the upper surface of hot plate 1 is fixed with two at least reference column 3, and template 2 is located the top of hot plate 1, has seted up two at least through-holes 23 on template 2, through-hole 23 and reference column 3 one-to-one, and reference column 3 passes through-hole 23, is provided with a plurality of DBC board along the length direction interval on template 2 and places a mouthful 21 a.

As shown in fig. 2 and 3, at least two mounting holes 71 are formed in the copper base plate 7, the mounting holes 71 correspond to the positioning columns 3 one by one, when the copper base plate 7 is placed, the mounting holes 71 are connected with the positioning columns 3 in an inserting manner, the copper base plate 7 is limited in the horizontal direction by the matching structure of the mounting holes 71 and the positioning columns 3, the middle part of the lower surface of the copper base plate 7 is attached to the upper surface of the heat conduction block 6, and gaps are formed between other parts of the lower surface of the copper base plate 7 and the upper surface of the heating plate 1; next, the template 2 is pressed on the copper bottom plate 7, the DBC plate is placed in the DBC plate placing opening 21a, the DBC plate abuts against the upper surface of the copper bottom plate 7, the DBC plate placing opening 21a limits the DBC plate, and the DBC plate is prevented from translating. Heating board 1 heats, and on the heat transfer of heating board 1 arrived heat conduction piece 6, heat transfer of heat conduction piece 6 arrived copper base plate 7, the heat from the middle part of copper base plate 7 to diffusion all around, because the middle part of copper base plate 7 lower surface and 6 direct contact of heat conduction for the middle part temperature of copper base plate 7 lower surface risees fast, and the temperature all around of copper base plate 7 lower surface risees slowly. Because the coefficient of heat conductivity of heat conduction piece 6 is less than the coefficient of heat conductivity of hot plate 1, in the in-process of heating hot plate 1, the temperature of hot plate 1 is higher than the temperature of heat conduction piece 6, there is the clearance between other positions except the middle part of copper bottom plate 7 lower surface and the upper surface of hot plate 1, hot plate 1 heats other positions except the middle part of copper bottom plate 7 lower surface through the heat radiation, make other positions except the middle part of copper bottom plate 7 lower surface heat up equally fast, and then make the lower surface of copper bottom plate 7 wholly be heated evenly, avoid appearing the condition of local overheat and high temperature, make DBC board and copper bottom plate 7 welded in-process copper bottom plate 7 not take place to warp, copper bottom plate 7 can fully contact with the radiator, improve the radiating efficiency of IGBT module.

Further, as shown in fig. 2, the groove 1a is arranged along the width direction of the heating plate 1, and the front end and the rear end of the groove 1a are both open, the heat-conducting block 6 can slide into the groove 1a from one end of the groove 1a or slide out of the groove 1a from one end of the groove 1a, and the heat-conducting block 6 is convenient to mount and dismount. Seted up opening 21 on template 2, opening 21 is the rectangle form and arranges along template 2's length direction, all have a plurality of boss 22 on the relative both sides wall in opening 21, a plurality of boss 22 sets up along template 2's length direction interval on corresponding lateral wall, boss 22 one-to-one on two lateral walls, two boss 22 that set up relatively form a boss group, a plurality of boss group cuts apart opening 21 into a plurality of DBC boards with opening 21 and places a mouth 21a, when the DBC board is located the DBC board and places a mouth 21a, the DBC board leans on with boss 22 counterbalance, boss 21a carries on spacingly to the DBC board.

As shown in fig. 1 and 3, the positioning plate 4 is located above the template 2, at least two sliding holes 41 are formed in the positioning plate 4, the sliding holes 41 correspond to the positioning columns 3 one by one, the positioning columns 3 penetrate through the sliding holes 41, the positioning plate 4 can slide up and down, a supporting table 44 is arranged on the lower surface of the positioning plate 4, the positioning plate 4 is rectangular, the four supporting tables 44 are distributed at four corners of the lower surface of the positioning plate 4, the sliding holes 41 penetrate through the supporting table 44, the supporting table 44 can abut against the upper surface of the template 2, and when the supporting table 44 abuts against the upper surface of the template 2, a gap is formed between the lower surface of the positioning plate 4 and the upper surface of the template 2, so that the heat dissipation of the DBC; a plurality of observation ports 42 are formed in the positioning plate 4, the observation ports 42 correspond to the DBC plate placing ports 21a one by one, a separation bar 43 is arranged between the adjacent observation ports 42, the separation bar 43 is provided with a separation column 5 capable of sliding vertically, when the DBC plate is placed in the DBC plate placing port 21a, the separation column 5 moves downwards, the lower end of the separation column 5 abuts against the copper bottom plate 7, and the separation column 5 is located between the two bosses 22 which are arranged oppositely, so that the adjacent DBC plates are further separated.

Example 2

This embodiment is substantially the same as embodiment 1 described above, except that: the heating plate 1 in this embodiment is made of an aluminum material, and the heat conduction block 6 is made of an iron material.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein may be made by those skilled in the art without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims (10)

1. The utility model provides a mould is used in welding of IGBT module, includes hot plate (1), its characterized in that, the upper surface of hot plate (1) is provided with heat conduction piece (6), the coefficient of heat conductivity of heat conduction piece (6) is less than the coefficient of heat conductivity of hot plate (1).

2. The die for welding the IGBT module according to claim 1, wherein a groove (1a) is formed in the middle of the upper surface of the heating plate (1), and the heat-conducting block (6) is embedded in the groove (1 a).

3. The die for welding the IGBT module according to claim 2, wherein the grooves (1a) are arranged along the width direction of the heating plate (1), and the front and rear ends of the grooves (1a) are open.

4. The mold for welding the IGBT module according to claim 1, further comprising a template (2) positioned above the heating plate (1), wherein the template (2) can slide up and down relative to the heating plate (1), and a plurality of DBC plate placing openings (21a) are arranged on the template (2) at intervals along the length direction.

5. The mold for welding the IGBT module according to claim 4, wherein the template (2) is provided with through openings (21), the through openings (21) are rectangular and arranged along the length direction of the template (2), two opposite side walls in the through openings (21) are respectively provided with a plurality of bosses (22), the plurality of bosses (22) are arranged on the corresponding side walls at intervals along the length direction of the template (2), and the bosses (22) on the two side walls are in one-to-one correspondence.

6. The die for welding the IGBT module according to claim 4, wherein at least two positioning columns (3) are fixed on the upper surface of the heating plate (1), at least two through holes (23) are formed in the template (2), the through holes (23) correspond to the positioning columns (3) one by one, and the positioning columns (3) penetrate through the through holes (23).

7. The mold for welding the IGBT module according to claim 6, further comprising a positioning plate (4) positioned above the template (2), wherein at least two sliding holes (41) are formed in the positioning plate (4), the sliding holes (41) correspond to the positioning posts (3) one by one, and the positioning posts (3) penetrate through the sliding holes (41); a plurality of observation ports (42) are formed in the positioning plate (4), and the observation ports (42) correspond to the DBC plate placing ports (21a) one by one.

8. The welding die for the IGBT module according to claim 7, wherein a separation bar (43) is arranged between adjacent observation ports (42), and the separation bar (43) is provided with a separation column (5) capable of sliding vertically.

9. The die for welding the IGBT module according to claim 7, wherein the positioning plate (4) has a support table (44) on the lower surface thereof, and the support table (44) can abut against the upper surface of the template (2).

10. The die for welding an IGBT module according to claim 1, characterized in that the heating plate (1) is made of aluminum material and the heat conducting block (6) is made of graphite material.

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