JP3618200B2 - Method for manufacturing ceramic substrate and electronic circuit device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for manufacturing a ceramic substrate for manufacturing a high-density circuit board made of ceramic, and a method for manufacturing an electronic circuit device for manufacturing an electronic circuit device in which an electronic circuit element such as a semiconductor device is mounted on the ceramic substrate.
[0002]
[Prior art]
FIG. 14 is a view showing a conventional method of manufacturing an electronic circuit device. In the step shown in FIG. 14A, holes 70 are formed in the multi-piece green ceramic substrate 1 by the punch 2. Next, in the step shown in FIG. 14B, the conductor 4 for electrically connecting the upper and lower sides is buried in the hole 70 formed by the punch 2. Subsequently, in the step shown in FIG. 14C, the planar wiring material 5 is printed on the surface. In the step shown in FIG. 14 (d), several to several tens of the green ceramics thus produced are stacked and pressed to form a laminated body 6 ′. Next, in the step shown in FIG. 14 (e), the fired ceramic 7 ′ is manufactured by placing the laminated body 6 ′ in a furnace and firing it. Next, in the step shown in FIG. 14 (f), the fired ceramic 7 ′ is bonded to the cutting table 8 with wax in order to perform necessary division. Next, in the step shown in FIG. 14 (g), dicing with a diamond blade (not shown) while flowing a grinding liquid (not shown) on the fired ceramic 7 'bonded to the cutting table 8 with wax. Then, it is divided into each individual fired ceramic substrate 9 '. Next, in the step shown in FIG. 14 (h), the wax is warmed and the individual ceramic 9 'is removed. Next, in the step shown in FIG. 14 (i), the individual fired ceramic substrate 9 ′ can be obtained by washing the adhered wax 10.
[0003]
Finally, in the step shown in FIG. 14 (j), the electronic circuit device was able to be manufactured by mounting the LSI chip 11 on the fired ceramic substrate 9 ′ obtained individually.
Also, as a conventional technology for cleaving ceramic instead of dicing,
(1) “Laser Cleavage” Toshihiro Okiyama Journal of Precision Engineering Vol. 2,1994, P196-199
(2) Japanese Patent Laid-Open No. 3-489
(3) Japanese Patent Laid-Open No. 4-167985
(4) Japanese Patent Laid-Open No. 4-37492
Etc. were known.
[0004]
[Problems to be solved by the invention]
In the above-described prior art, the drilling of green ceramics has a problem that the speed is limited by the mechanical movement speed, and punching becomes difficult when the hole diameter is smaller than 0.1 mm. Further, regarding the division of the ceramic after firing, there is a problem that the diamond blade is cut at a high speed and cooled with a grinding liquid, so that it becomes wet processing, the speed is slow, and the blade is severely worn. There is also a problem that a cutting width is necessary. In addition, the wax used for mounting needs to be washed and removed sufficiently, and here also a wet process is indispensable, which requires a large number of man-hours, a washing device and a lot of water for washing.
[0005]
The object of the present invention is to improve the mounting density by enabling the drilling of the raw ceramic smaller than about 0.1 mm to improve the filling property of the conductor, in order to solve the above problems, and in a dry process. An object of the present invention is to provide a method for manufacturing an electronic circuit device on which a ceramic substrate and an LSI chip are mounted, in which a divided fired ceramic substrate on which an LSI chip can be mounted is manufactured to reduce processes and man-hours.
Another object of the present invention is to improve the mounting density by making holes with a conductor filling property smaller than about 0.1 mm with respect to the raw ceramic, and further, the LSI chip can be manufactured by a dry process. A ceramic that is capable of manufacturing a reliable fired ceramic substrate at a high yield while manufacturing a mountable divided fired ceramic substrate without damaging the through-hole conductors and wiring. An object of the present invention is to provide a method for manufacturing an electronic circuit device on which a substrate and an LSI chip are mounted.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides a drilling process in which a raw ceramic is irradiated with a laser beam to perform a drilling process based on the removal, and a conductor is placed in the hole formed in the raw ceramic by the drilling process. The conductor filling step for filling, the wiring conductor forming step for forming a desired wiring conductor on the plane of the raw ceramic by printing, and the raw ceramic formed with the conductor in the conductor filling step and the wiring conductor forming step are stacked and pressurized. A stacking step, a firing step of firing the laminated body pressed in the stacking step to obtain a fired ceramic substrate, and a cutting line along the dividing line to be divided with respect to the fired ceramic substrate fired in the firing step. And a cleaving step of cleaving by generating a heating stress by irradiating a laser beam in a focused state.
Further, the present invention is characterized in that, in the drilling step in the ceramic substrate manufacturing method, one drilling process is performed by irradiating a laser spot multiple times in a circumferential shape. Further, in the drilling step in the ceramic substrate manufacturing method, the present invention monitors and determines whether or not the hole is an incomplete hole by monitoring the transmitted light of the laser beam from the processed hole or the image of the processed hole. Only a complete hole is irradiated again with a laser beam and is reprocessed. The present invention further includes a groove forming step of forming a groove for inducing a cleaving in the cleaving step at least at an end portion of the cleaving line on the back surface of the laminate before the firing step in the ceramic substrate manufacturing method. It is characterized by.
[0007]
Further, the present invention is characterized in that in the cleaving step in the method for producing a ceramic substrate, mechanical stress is applied to at least a cleaving line on a side surface of the fired ceramic substrate. Further, the present invention is characterized in that in the cleaving step in the method for producing a ceramic substrate, a thermal stress is applied to at least a cleaving line on a side surface of the fired ceramic substrate.
Further, the present invention is characterized in that in the cleaving step in the method for producing a ceramic substrate, at least a cleaving line on a side surface of the fired ceramic substrate is processed. The present invention is also characterized in that a pulsed laser beam obtained from a Q-switched YAG laser light source is used as the laser beam in the drilling step in the ceramic substrate manufacturing method. Further, the present invention is characterized in that far-infrared laser light is used as the laser light in the cleaving step in the ceramic substrate manufacturing method. Further, in the cleaving step in the method for manufacturing a ceramic substrate, the present invention provides CO as a laser beam. ₂ Laser light is used.
[0008]
Further, in the present invention, in order to increase the speed in the drilling step in the ceramic substrate manufacturing method, the laser beam is scanned and rotated by a pair of galvanometer mirrors that can scan both the X and Y axes. .
Further, the present invention provides a drilling step for performing drilling processing based on removal by irradiating a raw ceramic with laser light, and a conductor filling step for filling a conductor into a hole drilled in the raw ceramic by the drilling step; A wiring conductor forming step for forming a desired wiring conductor on the plane of the raw ceramic by printing, a laminating step for laminating and pressing the raw ceramic on which a conductor is formed in the conductor filling step and the wiring conductor forming step, and the lamination A firing step of firing the laminated body pressed in the process to obtain a fired ceramic substrate, and a laser beam in a defocused state along a cutting line to be divided with respect to the fired ceramic substrate fired in the firing step A cleaving step of cleaving by generating heating stress by irradiation, and a mounting step of mounting an LSI chip on the individual ceramic substrate cleaved by the cleaving step A method for producing an electronic circuit device, characterized in that it comprises.
[0009]
As described above, according to the above-described configuration, the raw ceramic is smaller than about 0.1 mm, and it is possible to make a hole with improved conductor filling property to improve the mounting density. It is possible to reduce the number of processes and man-hours by manufacturing a divided fired ceramic substrate on which chips can be mounted.
In addition, according to the above configuration, it is possible to improve the mounting density by enabling the drilling with the conductor filling property smaller than about 0.1 mm, and mounting the LSI chip by dry process. A high-yield electronic circuit device mounted with a reliable ceramic substrate and LSI chip, while reducing the number of processes and man-hours by manufacturing a split ceramic substrate without damaging the through-hole conductors and wiring. Can be manufactured.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of a method for manufacturing a ceramic substrate and an electronic circuit device according to the present invention will be described with reference to the drawings.
FIG. 1 is a process diagram showing an embodiment of a method of manufacturing an electronic circuit device according to the present invention.
As shown in FIG. 1 (i), the electronic circuit device is configured by mounting an LSI chip 11 on a fired and divided ceramic substrate 9.
First, FIG. 1A shows a through-hole drilling process in a large number of raw ceramic substrates using a laser beam 21. In this step, holes 3 are successively formed in the raw ceramic substrate 1 by the laser light 21 collected by the objective lens 36. That is, the raw ceramic substrate 1 is successively drilled by the laser drilling apparatus shown in FIG. Whether or not the hole has passed is monitored and confirmed by the CPU in the control device 41 by monitoring with a light detector 37 provided in the lower part, and the address of the insufficient one is stored and is on the raw ceramic substrate 1. After the hole has been processed for the region or after the final hole has been processed on the raw ceramic substrate 1, only those with insufficient holes are additionally processed to eliminate clogged holes.
[0011]
Next, FIG. 1B shows a process of embedding a conductive material in the through hole. In this step, a conductor 4 such as W for electrically connecting the upper and lower sides is embedded in each hole 3.
Subsequently, FIG. 1C shows a planar wiring printing process on the surface of the raw ceramic substrate. In this step, a planar wiring material 5 is formed on the surface of the raw ceramic substrate 1 by printing or the like.
Next, FIG. 1D shows a stacking process. In this step, several to several tens of green ceramics of each layer made as described above are stacked and pressed to manufacture the laminate 6.
Next, FIG. 1E shows a split groove forming step on the back surface for forming the split grooves 22 on the back surface of the laminate 6. In this step, the groove 22 is formed on the back surface of the laminated body 6 along the line to be divided before the laminated body 6 is fired in a furnace. The reason why the groove 22 is formed is to prevent the jump 94 from being generated without splitting straight at the end when the groove 22 is divided in the dividing step shown in FIG. Therefore, when dividing, the groove 22 may be formed only in the end portion. The width of the groove is about 0.1 mm to 1.0 mm, the depth of the groove is about 0.05 mm to 0.5 mm, and the width and depth are about 10% or less of the thickness of the laminate 6, respectively. It is. The groove is formed by rolling a roller with a metal blade, pressing a knife-like object, or in the case of a mass product with a fixed size, attach a plate with a grooved part in advance under the pressure jig. There is a way to keep it.
[0012]
Next, FIG.1 (f) shows the baking process which puts into a furnace and bakes. In this step, the laminated body 6 having the split grooves 22 formed on the back surface is put into a furnace and fired to produce a hard fired ceramic 7.
Subsequently, FIG. 1 (g) shows a dividing step of dividing into individual fired ceramic substrates by laser heating stress. In this step, the wafer is divided by a dividing apparatus using laser heating stress shown in FIG. That is, the manufactured hard fired ceramic 7 is fixed to the vacuum suction table 77, and the focused laser beam 23 whose beam diameter is widened out of focus is irradiated to the fixed fired ceramic 7 along the dividing line. As a result, heating stress is generated, and the cleaving occurs accurately along the groove formed before firing from one end to the other, so that an individual fired ceramic substrate 9 is obtained as shown in FIG. Become.
[0013]
Since wax bonding is not used here, cleaning is unnecessary, and it is possible to immediately mount the LSI chip 11 and the like by the mounting process shown in FIG.
[0014]
Next, an embodiment of a laser drilling apparatus used in the through-hole drilling process in the raw ceramic substrate shown in FIG. 1A will be described with reference to FIGS. FIG. 2 is a block diagram showing an embodiment of the laser drilling apparatus according to the present invention. A large number of raw ceramic substrates 1 are placed on a stage 38 that is stepped and repeated at predetermined intervals in the X and Y axis directions. A pulse laser beam 21 of several to several tens of kHz having a pulse width of about 30 to 200 ns with a high output of several to several tens of watts emitted from a laser oscillator 31 composed of a Q-switched YAG laser oscillator or the like is used for optical axis alignment. The condensing lens 36 passes through the two tilting mirrors 32 and 33 and is scanned with a circular light for several to several tens of pulses per hole with respect to one hole by the galvanometer mirrors 32 and 35 for laser light scanning. The raw ceramic 1 is squeezed and irradiated, and one hole is formed (a hole diameter is about 0.1 mm or less) repeatedly at a desired pitch. Thereby, it becomes possible to make the hole 3 of about 100 to 300 per second. At this time, it is known whether or not one hole is sufficiently opened by monitoring the transmitted light amount of the laser beam with the light detector 37 on the back side, and the hole which has not been sufficiently transmitted through the control unit 4 is not yet confirmed. This is stored in the through hole memory 42. After the hole processing is finished for a certain area on the raw ceramic substrate 1 or after the final hole processing is finished on the raw ceramic substrate 1, the address of the non-through hole stored in the non-through hole memory 42 is called again. Processing. By doing so, clogged holes can be eliminated (set to 0). As for the drilling position, by connecting the CAD 44 to the control unit 41, any hole position can be freely machined by the control from the control unit 41 to the galvano mirrors 32 and 35 for laser beam scanning and the control to the stage 38. be able to. Reference numeral 39 denotes an observation optical system having an imaging device such as a TV camera for observing the position where the laser beam 21 is irradiated, and is used for adjusting the mirrors 32 and 33 and the like. That is, the mirrors 32 and 33 are adjusted so that the laser light 21 observed by the observation optical system 39 having the imaging device is positioned on the optical axis. The observation optical system 39 is used for positioning the stage 38. Further, it is assumed that the light detector 37 has a field of view in which each of the plurality of holes can detect the amount of laser light scanned and transmitted by the galvanometer mirrors 32 and 35 for laser light scanning. This is because the pulse laser beam 21 is scanned with the galvanometer mirrors 32 and 35 for scanning the laser beam to process a plurality of holes on the raw ceramic substrate 1 at a desired pitch.
[0015]
FIG. 3 is a view showing a method of irradiating laser light at the time of drilling. As shown in FIG. 3C, a pulse laser focused light 46 (several to several tens of mJ / pulse) emitted from a Q-switched YAG laser (near infrared light having a wavelength of about 1.06 μm) is used for laser light scanning. The galvanometer mirrors 32 and 35 are irradiated from the center of the hole several times to several tens of times under the control of the control unit 41, and the locus is as shown in 47 as shown in FIG. As a result, as shown in FIG. 3A, the good holes 3 can be formed two-dimensionally at a desired pitch in the raw ceramic substrate 1.
[0016]
FIG. 4 is a diagram showing a clogging-free (0) drilling sequence according to the present invention. FIG. 4A shows a schematic configuration related to the drilling sequence, and FIG. 4B is a flowchart showing the drilling sequence. Step 51 shows a process in which the pulsed laser light 21 condensed by the objective lens 36 is made into a hole in the raw ceramic substrate 1 and the hole is made. Step 52 shows a step of measuring the laser light that has been drilled in Step 51 and transmitted through the raw ceramic substrate 1 with the photodetector 37. Step 53 is a step of determining the opening degree of the hole based on the transmitted light amount measured by the light detector 37 in the control unit 41. Step 54 determines whether the drilling is completed (OK) or incomplete (insufficient) according to the opening degree of the hole determined by the control unit 41. Is stored in the non-through hole memory 42. The address (positional coordinate) of the non-through hole can be obtained from the control signal to the galvano mirrors 32 and 35 for laser beam scanning and the position coordinate of the stage obtained from the stage 38 in the control unit 41. In the above embodiment, in steps 52 to 53, the transmitted light amount of the laser light irradiated through the processed hole is measured by the light detector 37, and the holed state (the clogged state) is set in the control unit 41. However, an illumination light source is provided on the back surface of the raw ceramic 1, and an image through the hole that has been drilled is picked up by the image pickup device 39, and the control portion 41 picks up the image picked up by the image pickup device 39. It is possible to calculate the area of the processed hole from the image signal of the hole, and to recognize and determine whether or not it is incomplete (insufficient) based on the calculated area of the processed hole.
[0017]
In step 56, when the hole processing is completed for a certain region on the raw ceramic substrate 1 or the final hole processing is completed on the raw ceramic substrate 1, the control unit 41 stores the unprocessed holes stored in the non-through hole memory 42 in step 57. The address (positional coordinate) of the through hole is read, the laser processing is performed again on the read non-through hole, the laser beam transmitted in step 58 is measured by the light detector 37, and the light detection is performed in step 59. The hole penetration determination is performed by determining the opening degree of the hole based on the transmitted light amount measured by the device 37. In step 60, it is determined whether the drilling is complete (OK) or incomplete (insufficient) according to the opening degree of the hole determined in the control unit 41. If incomplete (insufficient), the address of the unpenetrated hole is determined in step 61. Is stored in the non-through hole memory 42. In step 56, when the hole machining is completed for a certain region on the raw ceramic substrate 1 or the final hole machining is finished on the raw ceramic substrate 1, the control unit 41 stores the unprocessed holes stored in the non-through hole memory 42 in step 62. The address (positional coordinate) of the through hole is read, and laser processing is performed again on the read non-through hole.
[0018]
As described above, the process is repeated until the non-through hole becomes zero in step 63. Normally, the non-through hole becomes 0 in the second processing. As described above, when the drilling process is performed by irradiating the raw ceramic 1 with the pulse laser beam, the heating evaporation removal process can be performed at a high speed up to a hole diameter of about 0.1 mm or less.
FIG. 5 is a cross-sectional view showing the difference in laser drilling compared to conventional punch drilling. FIG. 5A shows a cross section of a through hole 70 by punching a conventional green ceramic substrate 1, and FIG. 5B shows a cross section of the through hole 3 by laser drilling of the green ceramic substrate 1 according to the present invention. Show. The hole 70 formed in the raw ceramic substrate 1 by conventional punching has a straight line that is a characteristic of machining, so the corner of the end is sharp and the filling property when embedding a conductor is small. It gets worse. On the other hand, when a hole is made in the raw ceramic substrate 1 by the laser beam according to the present invention, since it is a heat evaporation removal process, as shown in FIG. On the other hand, it has the effect of improving the filling property of the conductor, and the hole diameter of about 5,000 to 20,000 per minute can be made about 0.1 mm because the hole 3 of about 100 to 300 per second can be made. This can be realized as follows.
[0019]
Next, an example of the laser heating cleaving apparatus used in the dividing step by the laser heating stress shown in FIG. 1 (g) will be described with reference to FIGS. FIG. 6 is a block diagram showing an embodiment of the laser heating cleaving apparatus according to the present invention. The laser heating cleaving apparatus includes a control unit 71 that controls the laser power source 72 and the stage 76, and a CO that emits far-infrared light having a wavelength of about 10.6 μm that is turned on and off based on the control power source from the laser power source 72. ₂ A laser light source 73 composed of a gas laser light source or the like; a half mirror 80 that reflects far-infrared laser light 74 emitted from the laser light source 73; a condenser lens 75 that condenses the far-infrared laser light 74; A vacuum suction plate 77 for vacuum-sucking the fired ceramic substrate 7 is placed, and a stage 76 configured to be movable in the X and Y axis directions according to a command from the control unit 71, and laser light 74 is emitted on the fired ceramic substrate 7. A gas nozzle 79 that blows air or dry nitrogen to cool the periphery of the irradiated portion irradiated in the defocused state, a gas supply pipe 78 that supplies air or dry nitrogen to the gas nozzle 79, and the fired ceramic substrate 7. An observation optical system 81 having an imaging device such as a TV camera for observing the position irradiated with the laser beam 74 through the half mirror 80 Constructed.
[0020]
Then, a signal is sent from the control unit 71 to the laser power source 72, and CO light that emits far-infrared light having a wavelength of about 10.6 μm. ₂ A laser beam 74 is emitted from a laser light source 73 composed of a gas laser light source and the like, condensed by a condenser lens 75, and defocused on the surface of the fired ceramic substrate 7 (6 mm in a defocused state about 10 mm away from the focus position). Irradiate at a certain spot). In this irradiation state, the stage 76 is moved along the cleaving groove 22. The ceramic 7 is placed on a vacuum absorbing plate 77. At the time of laser irradiation, the surface is cooled with air or dry nitrogen supplied from the gas supply pipe 78 to the gas nozzle 79 so as to increase the temperature gradient around the irradiated portion. As described above, when the surface of the fired ceramic substrate 7 is irradiated with the laser beam 74 in a defocused state, a heating stress is generated and the surface is cut. In particular, by cooling the periphery of the irradiated portion irradiated with the laser beam 74 in the defocused state, as shown in FIG. Therefore, it is possible to achieve accurate cleaving along the cutting line. That is, when the periphery of the irradiated part is cooled by air or dry nitrogen or the like, a large temperature gradient is produced from 92 to 93 and a large heating stress is concentrated along the breaking line 91, and along the breaking line. Accurate cleaving can be realized.
[0021]
Note that, as shown in FIG. ₀ = Through the relationship of irradiating a spot light of about 6 mm, there is a through hole 3 in which a conductor 4 such as W is embedded in the vicinity of the breaking line, and this conductor 4 is exposed to a laser spot light. 4 emits far-infrared light having a similar absorption characteristic to this conductor and ceramic so that the wavelength does not evaporate. ₂ It is necessary to use a gas laser beam.
If YAG laser light is used for cleaving, if the laser spot light in the defocused state is applied to the conductor 4, the conductor 4 evaporates explosively due to good absorption characteristics. The conductor 4 that is present is lost. Therefore, for example, CO that emits far infrared light ₂ It is desirable to use a gas laser beam.
[0022]
Further, at the end of the dividing line to be divided, the heating stress escapes, and as shown in FIG. 8, it is not broken along the breaking line 91 irradiated with the laser beam, but cracks in any direction. As a result, a splash 94 is generated. Therefore, in order to prevent the jump 94 that occurs at the end of the dividing line 91 to be divided, it is necessary to take measures as described below.
That is, as shown in FIG. 1E, by forming the dividing groove 22 on the back surface of the laminated body 6, it becomes possible to cleave along the dividing groove 22 particularly at the end of the breaking line. As shown, it is possible to prevent the splash 94 from occurring at the end of the breaking line 91.
Next, another embodiment for preventing the splash 94 will be described with reference to FIGS. In each of FIGS. 9 to 11, by pressing the point where the side surface of the fired ceramic substrate 7 and the cutting line intersect with a spring or the like to apply a symmetric stress to the cutting line, it is possible to perform the accurate cutting to the end with higher accuracy. This is an example. FIG. 9 shows an embodiment in which a wedge jig 81 having a sharp tip is pressed by a spring 82. FIG. 10 shows an embodiment in which a wedge jig 81 having a sharp tip is pressed by a piezo element 83. FIG. 11 shows an embodiment in which a heating means 84 is provided that makes the tip of the wedge jig 81 sharpened by some kind of pressing means to a high temperature. In the embodiment shown in FIG. 11 (a), as shown in FIG. 11 (b), the end of the cleaving line is subjected to symmetrical stress due to both effects of pressurization and heating, and accurate cleaving can be induced. It becomes.
[0023]
In addition, FIG. 12 shows CO 2 that emits far-infrared light having a wavelength of about 10.6 μm instead of applying stress by a wedge. ₂ The beam diameter of a laser beam emitted from a laser light source 73 composed of a gas laser light source or the like is enlarged by a beam diameter enlarging optical system, and a plurality of rectangular beams 102 are formed through a plurality of slit-like rectangular openings 101. An embodiment will be described in which a rectangular beam 102 is condensed on a linear beam 104 by a cylindrical lens 103 and the end side surface of the breaking line 91 is heated in a defocused state to generate a symmetric thermal stress distribution. That is, as shown in FIG. 12A, the side surface of the breaking line 91 is irradiated with the linear beam 104 in a defocused state and heated, and as shown in FIG. By generating the nominal thermal stress distribution, it is possible to lead to accurate cleaving without causing a jump.
Moreover, FIG. 13 shows the Example which pre-processes to the edge part side surface of a cleaving line, and obtains an exact cleaving. Preliminary processing can be performed by rolling a roller with a metal blade, pressing a knife-like one, or irradiating a laser beam to form a groove.
[0024]
【The invention's effect】
According to the present invention, for a raw ceramic, it is possible to make a hole that is smaller than about 0.1 mm and improve the filling property of the conductor to improve the mounting density, and further, it is possible to mount an LSI chip by a dry process. The produced fired ceramic substrate is manufactured to reduce the number of steps and man-hours, and at the same time, it is possible to save resources and save energy by dry production.
In addition, according to the present invention, it is possible to improve the mounting density by making a hole smaller than about 0.1 mm and improving the filling property of the conductor with respect to the raw ceramic, and it is possible to mount an LSI chip by a dry process. Effect of manufacturing a highly divided sintered ceramic substrate without damaging the through-hole conductors and wirings, reducing the number of processes and man-hours, and manufacturing a reliable electronic circuit device at a high yield Play.
[Brief description of the drawings]
FIG. 1 is a process diagram showing an embodiment of a method of manufacturing an electronic circuit device according to the present invention.
FIG. 2 is a configuration diagram showing an embodiment of a laser drilling apparatus used in a raw ceramic drilling process according to the present invention.
FIG. 3 is a view for explaining a laser beam irradiation method in drilling a raw ceramic according to the present invention.
FIG. 4 is a diagram showing a sequence that realizes no clogging (0) of raw ceramic drilling according to the present invention.
FIG. 5 is a comparative cross-sectional view of the drilling of the present invention and conventional punch drilling.
FIG. 6 is a block diagram showing an embodiment of a laser heating cleaving apparatus used for firing ceramic cleaving according to the present invention.
In the laser heating cleaving apparatus shown in FIG. 6, by cooling the periphery of the irradiated portion irradiated with laser light, a large temperature gradient is attached and a large heating stress is concentrated along the cleaving line. It is a figure for demonstrating implement | achieving exact cleaving along.
FIG. 8 is a diagram showing a jump that occurs when cleaving.
FIG. 9 is a view showing an embodiment in which side restraints are applied in order to make the fired ceramic cleaving according to the present invention more accurate and accurate.
FIG. 10 is a view showing another embodiment in which side restraint is applied in order to make the fired ceramic cleaving according to the present invention more accurate and accurate.
FIG. 11 is a view showing an embodiment in which side restraint and heating are applied in order to make the fired ceramic cleaving according to the present invention more accurate and accurate.
FIG. 12 is a view showing an embodiment in which heating is applied by irradiating a side surface with a linear beam in order to make the fired ceramic cleaving according to the present invention more accurate and accurate.
FIG. 13 is a view showing an example in which a side surface is preliminarily processed in order to make the fired ceramic cleaving according to the present invention more accurate and accurate.
FIG. 14 is a diagram showing an example of a manufacturing process of a conventional electronic circuit device.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Raw ceramic substrate, 3 ... Hole (through hole), 4 ... Conductor, 5 ... Planar wiring material, 6 ... Laminated body, 7 ... Fired ceramic, 9 ... Individual fired ceramic substrate, 11 ... LSI chip, 21 ... Laser beam, 22 ... groove, 23 ... focused laser beam, 31 ... laser oscillator, 32 ... tilt mirror, 33 ... tilt mirror, 34 ... galvanometer mirror, 35 ... galvanometer mirror, 36 ... objective lens, 37 ... photodetector, 38 ... Stage, 41 ... Control unit, 42 ... Non-through hole memory, 46 ... Laser focused light, 47 ... Track, 71 ... Control unit, 72 ... Laser power source, 73 ... Laser light source, 74 ... Laser light, 75 ... Condensation Lens, 76 ... Stage, 77 ... Vacuum absorption plate, 78 ... Gas supply pipe, 79 ... Gas nozzle, 81 ... Wedge jig, 82 ... Spring, 83 ... Piezo element, 84 ... Heating means

Claims (11)

A drilling process in which a laser spot is scanned on a raw ceramic to irradiate a desired location a plurality of times to perform one drilling process one after another, and a conductor is drilled into the raw ceramic by the drilling process. A conductor filling step of filling the conductor, a wiring conductor forming step of forming a desired wiring conductor on the plane of the raw ceramic, and a lamination step of laminating and pressing the raw ceramic formed with the conductor in the conductor filling step and the wiring conductor forming step A firing step of firing the laminated body pressed in the lamination step to obtain a fired ceramic substrate, and a defocused state along a dividing line to be divided with respect to the fired ceramic substrate fired in the firing step And a cleaving step of cleaving by generating a heating stress by irradiating with a laser beam. 2. The method of manufacturing a ceramic substrate according to claim 1, wherein the one drilling process is performed by scanning the laser spot circumferentially around the center of the hole . In the drilling step according to claim 1, the transmitted light of the laser beam from the processed hole or the image of the processed hole is monitored to determine whether or not the hole is incomplete, and the laser light is applied only to the incomplete hole. A method for producing a ceramic substrate, characterized by re-irradiating and reworking. A method for producing a ceramic substrate, comprising: a groove forming step for forming a groove for inducing cleavage in the cleaving step at least at an end portion of the cleaving line on the back surface of the laminate before the firing step according to claim 1. . 2. The method for manufacturing a ceramic substrate according to claim 1, wherein mechanical stress is applied to at least a breaking line on a side surface of the fired ceramic substrate. 2. The method for manufacturing a ceramic substrate according to claim 1, wherein a thermal stress is applied to at least a breaking line on a side surface of the fired ceramic substrate. 2. The method for manufacturing a ceramic substrate according to claim 1, wherein the cutting process is performed on at least a breaking line on a side surface of the fired ceramic substrate. 2. The method for manufacturing a ceramic substrate according to claim 1, wherein a pulsed laser beam obtained from a Q-switched YAG laser light source is used as the laser beam. _{2. The} method for manufacturing a ceramic substrate according to claim 1, wherein a far infrared laser beam or a CO2 laser beam is used as the laser beam . 2. The cleaving process according to claim 1, further comprising cooling the periphery of the irradiated portion irradiated with the laser beam on the fired ceramic substrate . A drilling process in which a laser spot is scanned on a raw ceramic to irradiate a desired location a plurality of times to perform one drilling process one after another, and a conductor is drilled into the raw ceramic by the drilling process. A conductor filling step of filling the conductor, a wiring conductor forming step of forming a desired wiring conductor on the plane of the raw ceramic, and a lamination step of laminating and pressing the raw ceramic formed with the conductor in the conductor filling step and the wiring conductor forming step A firing step of firing the laminated body pressed in the lamination step to obtain a fired ceramic substrate, and a defocused state along a dividing line to be divided with respect to the fired ceramic substrate fired in the firing step Cleaving step of irradiating with laser light to generate heating stress and cleaving, and mounting an LSI chip on the individual ceramic substrate cleaved by the cleaving step Method of manufacturing an electronic circuit device, characterized in that it comprises a mounting process.

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