JP4151667B2 - Manufacturing method of physical quantity sensor and bonding apparatus - Google Patents

Description

  The present invention relates to a method of manufacturing a physical quantity sensor for measuring the azimuth and direction of a physical quantity such as magnetism and gravity, and a bonding apparatus used therefor.

2. Description of the Related Art Recently, mobile terminal devices such as mobile phones have appeared that have a GPS (Global Positioning System) function for displaying user position information. In addition to this GPS function, by providing a function for accurately detecting geomagnetism and a function for detecting acceleration, it is possible to detect the azimuth, direction, or movement direction in the three-dimensional space of the mobile terminal device carried by the user. it can.
In order to provide the mobile terminal device with the functions described above, it is necessary to incorporate a physical quantity sensor such as a magnetic sensor or an acceleration sensor in the mobile terminal device. Further, in order to be able to detect the orientation and acceleration in the three-dimensional space by such a physical quantity sensor, it is necessary to incline the installation surface of the physical quantity sensor chip.

Here, various types of physical quantity sensors described above are currently provided. For example, a magnetic sensor that detects magnetism and does not tilt the installation surface is known as one of them. This magnetic sensor is mounted on the surface of a substrate and is one magnetic sensor chip (physical quantity sensor chip) that is sensitive to magnetic components of external magnetic fields in two directions (X and Y directions) orthogonal to each other along the surface. And the other magnetic sensor chip that is placed on the surface of the substrate and is sensitive to the magnetic component of the external magnetic field in the direction perpendicular to the surface (Z direction).
This magnetic sensor measures the geomagnetic component as a vector in a three-dimensional space using the magnetic component detected by the pair of magnetic sensor chips.

  However, this magnetic sensor has the disadvantage that the thickness (height relative to the Z direction) increases because the other magnetic sensor chip is placed in a state of being perpendicular to the surface of the substrate. Therefore, in order to make the thickness as small as possible, a physical quantity sensor (see, for example, Patent Documents 1 to 3) in which the installation surface is inclined as described above is preferably used.

  Further, as this type of physical quantity sensor, there is an acceleration sensor as described in Patent Document 1. In this one-side beam structure acceleration sensor, the acceleration sensor chip (physical quantity sensor chip) is inclined in advance with respect to the mounting substrate, so that even if the sensor packaging is placed on the surface of the mounting substrate, it depends on the inclination direction. Further, the sensitivity in the predetermined axial direction can be kept high, and the sensitivity in the other axial direction including the direction along the surface of the substrate can be reduced.

  As described above, the physical quantity sensor in which the physical quantity sensor chips are inclined with respect to each other can be reduced in thickness while minimizing the thickness, and has various advantages associated with the inclination. .

For example, as shown in FIG. 11, this type of physical quantity sensor includes physical quantity sensor chips 81 and 82, a plurality of leads 83 for electrically connecting the physical quantity sensor chips 81 and 82 to the outside, and these. It consists of the resin mold part 84 fixed integrally. The physical quantity sensor chips 81 and 82 are disposed to be inclined with respect to the lower surface (bottom surface) 84 a of the resin mold portion 84.
When manufacturing the physical quantity sensor 80 described above, for example, the stage portions 85 and 86 of the lead frame are inclined by press working or the like, and then the physical quantity sensor chips 81 and 82 are mounted on the stage portions 85 and 86. . Thereafter, a wire 87 for electrically connecting the pads formed on the surfaces of the physical quantity sensor chips 81 and 82 and the leads 83 by wire bonding is disposed.

When performing this wire bonding, the tip of the capillary that discharges the wire 87 is pressed against the lead 83 and the pad, and both ends of the wire 87 are bonded to the lead 83 and the pad, respectively, while applying heat and ultrasonic vibration. The wire bonding is usually performed by a ball bonding method. In this ball bonding method, it is preferable that the bonding is usually performed with the direction of the capillaries perpendicular to the surface of the lead 83.
JP-A-9-292408 JP 2002-156204 A JP 2004-128473 A

However, since the surface of the stage part and the physical quantity sensor chip is inclined with respect to the surface of the lead, when the wire is joined by the ball bonding method, the bonding force between the wire and the pad of the physical quantity sensor chip is reduced. There is a problem of doing.
Further, in order to prevent a decrease in bonding force between the wire and the pad of the physical quantity sensor chip, it is necessary to increase the area of the pad, which makes it difficult to reduce the size of the physical quantity sensor chip or the physical quantity sensor.

  The present invention has been made to solve the above-described problems, and a physical quantity sensor manufacturing method capable of improving the bonding force between a wire and a pad of a physical quantity sensor chip without increasing the area of the pad. And it aims at providing the bonding apparatus used for this.

In order to solve the above problems, the present invention proposes the following means.
The invention according to claim 1 includes a stage portion on which a physical quantity sensor chip is placed on a surface, and a frame portion having a plurality of leads arranged around the stage portion, and the stage portion is inclined with respect to the frame portion. A bonding apparatus that uses a lead frame to electrically connect the physical quantity sensor chip mounted on the stage unit and the leads to each other by a wedge bonding method, and a base on which the lead frame is disposed; A wedge tool that is movably attached to a table and electrically connects the surface of each lead and the inclined surface of the physical quantity sensor chip with a wire, and the wedge tool is substantially parallel to the surface of the lead. A first flat surface sandwiching the wire together with the surface of the lead, and the physical quantity sensor chip Surface formed substantially parallel to a second planar surface sandwiching the wire together with the surface of the physical quantity sensor chip has proposed a bonding apparatus characterized in that it is provided.

  When the physical quantity sensor chip and each lead are electrically connected using the bonding apparatus according to the present invention, the physical quantity sensor chip is arranged on the surface of the stage portion of the lead frame in advance, and the physical quantity sensor chip and the stage The part is inclined with respect to the frame part. In this state, the surface of each lead and the surface of the physical quantity sensor chip are inclined with respect to each other. Next, the lead frame is placed on the base of the bonding apparatus while maintaining this inclined state.

Thereafter, one end of the wire discharged from the wedge tool is sandwiched between the second flat surface of the wedge tool and the bonding pad formed on the surface of the physical quantity sensor chip. In this state, heat or ultrasonic vibration is applied to bond one end of the wire to the bonding pad.
Thereafter, while discharging the wire from the wedge tool, the wedge tool is moved from the surface of the physical quantity sensor chip to the surface of the lead. Then, the other end of the wire discharged from the wedge tool is sandwiched between the first flat surface of the wedge tool and the surface of the lead. In this state, heat or ultrasonic vibration is applied to bond the other end of the wire to the surface of the lead.

Note that the wire may be bonded to the bonding pad after being bonded to the lead. That is, for example, first, the lead and one end of the wire are joined using the first flat surface, and then the bonding pad of the physical quantity sensor chip and the other end of the wire are joined using the second flat surface. It may be joined.
As described above, since the second flat surface and the surface of the physical quantity sensor chip and the first flat surface and the surface of the lead are arranged substantially in parallel when sandwiching the wire, the wedge Each flat surface of the tool can uniformly press both ends of the wire against each surface of the physical quantity sensor chip and the lead.

  According to a second aspect of the present invention, in the bonding apparatus according to the first aspect of the present invention, a guide groove that is formed to be recessed from the first flat surface and the second flat surface, and the guide groove for arranging the wire is provided in the first flat surface. A bonding apparatus is proposed which extends in a direction along each of a flat surface and the second flat surface.

According to the bonding apparatus according to the present invention, by inserting the wire into the guide groove, even if the wedge tool is moved between the physical quantity sensor chip and the lead, the wire discharged from the wedge tool can be reliably secured. It can hold | maintain in the state distribute | arranged to 1 flat surface and 2nd flat surface. Therefore, when the wire is bonded to the surface of the bonding pad or lead of the physical quantity sensor chip, the wire can be surely pressed against the surface of the bonding pad or lead by the first flat surface or the second flat surface of the wedge tool. it can.
In addition, since the position of the wire with respect to the first flat surface and the second flat surface is determined by the guide groove, the wire with respect to the surface of the bonding pad or lead can be simply adjusted by adjusting the position of the wedge tool with respect to the surface of the bonding pad or lead. Can be easily positioned.

  The invention according to claim 3 is the bonding apparatus according to claim 2, wherein the wedge tool is moved in the longitudinal direction of the guide groove at least in the vicinity of each surface of the lead and the physical quantity sensor chip. We have proposed a bonding device.

As described above, by forming the guide groove in the wedge tool, when the wedge tool is moved between the physical quantity sensor chip and the lead while discharging the wire from the wedge tool, the wire is not in the guide groove. It moves along the longitudinal direction. In the bonding apparatus according to the present invention, since the movement direction of the wedge tool coincides with the longitudinal direction of the guide groove, stress is generated in the wire due to the difference between the movement direction of the wire in the guide groove and the movement direction of the wedge tool. Can be prevented.
Since the wire is bonded to the surface of the physical quantity sensor chip and the lead, the movement direction of the wire and the movement direction of the wedge tool in the guide groove are different in the vicinity of the surface of the physical quantity sensor chip and the lead as described above. The stress becomes particularly large. Therefore, in the vicinity of the joint portion, the large stress can be prevented from occurring by making the moving direction of the wedge tool coincide with the longitudinal direction of the guide groove.

  According to a fourth aspect of the present invention, there is provided a preparatory step of preparing a lead frame having a stage portion on which a physical quantity sensor chip is placed on a surface, and a frame portion having a plurality of leads arranged around the stage portion; A stage tilting step for tilting with respect to the frame portion, an adhering step for bonding the physical quantity sensor chip to the stage portion, and a surface of each lead and the surface of the physical quantity sensor chip tilted by a wedge bonding method with a wire. A wiring step for electrical connection, and in the wiring step, a flat surface of a wedge tool used for the wedge bonding method is arranged substantially parallel to each surface of the lead and the physical quantity sensor chip, An object characterized by sandwiching the wire together with each surface of the lead and the physical quantity sensor chip We propose a method for producing a quantity sensor.

According to the physical quantity sensor manufacturing method of the present invention, when one end of the wire is joined to the bonding pad formed on the surface of the physical quantity sensor chip in the wiring step, one flat surface of the wedge tool and the physical quantity sensor chip One end of the wire is sandwiched by the surface of the wire. Further, when joining the other end of the wire to the lead, the other end of the wire is sandwiched between the other flat surface of the wedge tool and the surface of the lead.
As described above, when sandwiching the wire, in order to position each flat surface of the wedge tool substantially parallel to the surface of the physical quantity sensor chip, both ends of the wire are respectively connected to the physical quantity sensor chip and the flat surface of the wedge tool. It can be pressed evenly on each surface of the lead.

As described above, according to the first and fourth aspects of the invention, when the physical quantity sensor chip and each lead are electrically connected by a wire, both ends of the wire are two flat surfaces of the wedge tool. Thus, it is uniformly pressed against each surface of the physical quantity sensor chip and the lead. For this reason, the bonding strength between the physical quantity sensor chip and each surface of the lead and the wire can be improved.
Further, since it is not necessary to form a large bonding pad for the physical quantity sensor chip in order to improve the bonding force as in the prior art, the physical quantity sensor chip and the physical quantity sensor can be downsized.

Further, according to the invention according to claim 2, when bonding the wire to the surface of the bonding pad or the lead, the wire can be surely arranged on each flat surface of the wedge tool. It can be pressed against the surface of the pad or lead.
Furthermore, since the position of the wire with respect to each flat surface is determined by the guide groove, the wire can be easily positioned with respect to the surface of the bonding pad or the lead.

  According to the invention of claim 3, when the wedge tool is moved between the physical quantity sensor chip and the lead, the movement direction of the wedge tool is made to coincide with the longitudinal direction of the guide groove, whereby the wire is guided to the guide groove. Even if it moves along the longitudinal direction, since it can prevent that a stress generate | occur | produces in a wire, damage to a wire can be prevented.

FIG. 1 to FIG. 10 show an embodiment of the present invention. A magnetic sensor manufacturing method and a bonding apparatus according to this embodiment are adapted to the direction of an external magnetic field by two magnetic sensor chips inclined with respect to each other. The present invention is applied to a magnetic sensor (physical quantity sensor) that measures the size. This magnetic sensor is manufactured using a lead frame formed by pressing and etching a thin metal plate made of a thin copper plate or the like.
As shown in FIG. 1, the lead frame 1 includes two stage portions 7 and 9 on which magnetic sensor chips (physical quantity sensor chips) 3 and 5 formed in a rectangular plate shape in plan view are mounted, 9, and stage leads 7, 9 and connection leads 13 that connect the frame parts 11 to each other. The stage parts 7, 9, the frame parts 11, and the connection leads 13 are integrated. Is formed.

The frame portion 11 includes a rectangular frame portion 15 that is formed in a substantially rectangular frame shape so as to surround the stage portions 7 and 9, and a plurality of frames that protrude inward from the sides 15 a to 15 d of the rectangular frame portion 15. Lead 17.
A plurality of leads 17 are provided on each of the sides 15a to 15d of the rectangular frame portion 15, and are intended to be electrically connected to bonding pads (not shown) of the magnetic sensor chips 3 and 5. .

The two stage portions 7 and 9 are formed in a substantially rectangular shape in plan view so that the magnetic sensor chips 3 and 5 are placed on the surfaces 7a and 9a, respectively, and a pair of sides of the rectangular frame portion 15 facing each other. They are arranged side by side along 15b and 15d.
Two stage connecting portions 21 for connecting the two stage portions 7 and 9 to each other are formed at one end portions 7b and 9b of the two stage portions 7 and 9 facing each other. These stage connecting portions 21 are for preventing unnecessary wobbling of the stage portions 7 and 9, and can be easily deformed.

The connecting lead 13 protrudes from the respective corners 15 e to 15 h of the rectangular frame portion 15 toward the other end portions 7 c and 9 c of the stage portions 7 and 9. It connects with the side edge part located in the both ends by the side of the edge parts 7c and 9c. Here, the side end portions of the stage portions 7 and 9 indicate end portions in the width direction of the stage portions 7 and 9 orthogonal to the arrangement direction of the two stage portions 7 and 9.
An easily deformable portion 23 is formed at one end portion of the connecting lead 13 located on the other end portion 7c, 9c side of each stage portion 7,9. The easily deformable portion 23 is formed so as to be easily deformable in order to change the direction of the stage portions 7 and 9 about the axis L1 orthogonal to the thickness direction of the rectangular frame portion 15. Here, each axis L1 is orthogonal to the arrangement direction of the two stage portions 7 and 9.
The easily deformable portion 23 includes, for example, a concave groove that is previously recessed in the thickness direction of the lead frame 1 by photoetching, a notch portion that is cut out from the width direction of the connecting lead 13, and the like. These grooves and notches may be performed simultaneously when the lead frame 1 is formed on a thin metal plate, for example.

Next, a method for manufacturing a magnetic sensor using the lead frame 1 will be described.
First, the lead frame 1 described above is prepared (preparation process), and the lead frame 1 is pressed to change the orientation of the stage portions 7 and 9 around the axis L1, as shown in FIG. Tilt with respect to the frame portion 15 and the lead 17 (stage tilting step).
In this stage inclination process, the direction of the stage parts 7 and 9 changes centering on the axis line L1 because the easily deformable part 23 of the connection lead 13 and the stage connection part 21 are deformed by press working. Further, in the stage tilting step, the other end portions 7c, 9c of the stage portions 7, 9 are arranged at positions shifted in the thickness direction of the metal thin plate with respect to the rectangular frame portion 15 and the leads 17. In the lead frame 1, the stage portions 7 and 9 are inclined at a predetermined angle with respect to the rectangular frame portion 15 and the leads 17.

After this stage tilting step, the magnetic sensor chips 3 and 5 are bonded to the surfaces 7a and 9a of the stage portions 7 and 9 via silver paste, respectively (bonding step). A plurality of bonding pads 27 and 29 that are electrically connected to the leads 17 are formed on the surfaces 3a and 5a of the magnetic sensor chips 3 and 5, and these bonding pads 27 and 29 are arranged along the axis L1 in each stage. The parts 7 and 9 are arranged side by side on the other end parts 7c and 9c side.
After completion of the bonding process, as shown in FIG. 3, the bonding pads 27 and 29 of the magnetic sensor chips 3 and 5 and the respective leads 17 are connected to each other by a wedge bonding method using a bonding device 31. ) For electrical connection (wiring process).
The bonding apparatus 31 used here includes a base 33 on which the lead frame 1 is arranged, and a wedge tool 35 that arranges wires between the bonding pads 27 and 29 and the leads 17.

The base 33 is configured by providing a substantially wedge-shaped stage support portion 37 protruding from the flat surface 33a. The stage support portion 37 is formed with a pair of inclined surfaces 37a and 37b inclined with respect to the flat surface 33a of the base 33, and the stage portions 7 and 9 are arranged on the inclined surfaces 37a and 37b, respectively. It has become.
Therefore, in a state where the lead frame 1 is attached to the base 33, the rectangular frame portion 15 and the leads 17 are arranged on the flat surface 33 a of the base 33, and the stage portions 7 and 9 are on the surface of the stage support portion 37. Since it is arranged on 37a, 37b, the inclined state of each stage part 7, 9 with respect to the rectangular frame part 15 and each lead 17 can be maintained.
In the wiring process, heat and mechanical stress based on wire bonding are generated. Therefore, the base 33 is preferably formed from a metal that can withstand the heat and mechanical stress.

The wedge tool 35 is arranged such that the central axis L2 extending in the longitudinal direction thereof is substantially perpendicular to the flat surface 33a of the base 33, that is, the front end portion 35a of the surface 3a, 5a of the magnetic sensor chip 3, 5 The lead 17 is arranged to face the surface 17a. The wedge tool 35 can be translated with respect to the base 33 in a direction along the flat surface 33 a and in a direction orthogonal thereto, and can be rotated around the central axis L <b> 2 of the wedge tool 35.
As shown in FIG. 4, the front end portion 35a of the wedge tool 35 has a first flat surface 35b substantially orthogonal to the central axis L2 and a second flat surface 35c inclined with respect to the first flat surface 35b. Are formed adjacent to each other. The inclination angle between the two flat surfaces 35b and 35c is a relative inclination angle between the surfaces 3a and 5a of the magnetic sensor chips 3 and 5 and the surface 17a of the lead 17 disposed on the stage portions 7 and 9, respectively. It is almost equal.

  Recessed guide grooves 37a and 37b are respectively formed in the flat surfaces 35b and 35c so as to be recessed from the flat surfaces 35b and 35c, and extend linearly along the flat surfaces 35b and 35c. The two guide grooves 37a and 37b extend in a direction along the arrangement direction (GH direction) of the two flat surfaces 35b and 35c and are connected to each other. Wires are arranged in the guide grooves 37a and 37b, and play a role of moving the wires along the arrangement direction of the two flat surfaces 35b and 35c.

The depth dimension of each guide groove 37a, 37b is formed smaller than the diameter of the insertion hole 39 or the wire, and in the state where the wire is arranged in the guide groove 37a, 37b, a part of the wire is each flat surface 35b. , 35c. Further, the wedge tool 35 is formed with an insertion hole 39 for guiding the wire from the side 35d of the wedge tool 35 to the first flat surface 35b, and is connected to the end of the guide groove 37a of the first flat surface 35b. Has been.
Therefore, the wire inserted from the side portion 35d of the wedge tool 35 is guided by the two guide grooves 37a and 37b, and can move on the first flat surface 35b and the second flat surface 35c.

  The wiring process described above is performed using the bonding apparatus 31 configured as described above. In this wiring process, as shown in FIG. 5, first, one end of the wire 41 discharged from the wedge tool 35 is inserted into the bonding pad 29 disposed on the surface 5a of one magnetic sensor chip 5 through the insertion hole 39. Join.

  At this time, in a state where the wire 41 is arranged in the guide groove 37b of the second flat surface 35c, the wedge tool 35 is moved in the direction of the central axis L2, and the second flat surface 35c of the wedge tool 35 and the bonding pad are moved. 29, one end of the wire 41 is sandwiched. In this state, since the second flat surface 35c and the surface 5a of the magnetic sensor chip 5 are arranged substantially in parallel, the wire 41 arranged in the guide groove 37b is connected to the bonding pad 29 by the second flat surface 35c. It can be pressed evenly on the whole. In this state, one end of the wire 41 is joined to the bonding pad 29 by applying heat or ultrasonic vibration.

After the bonding of the wire 41 to the bonding pad 29 is completed, the surface of the one magnetic sensor chip 5 along the longitudinal direction (H direction) of the guide grooves 37a and 37b while discharging the wire 41 from the wedge tool 35. The wedge tool 35 is moved away from 5a. At this time, the wire 41 moves in the guide grooves 37a and 37b along the longitudinal direction thereof.
Then, the wedge tool 35 is moved to the tip 17c of the lead 17 adjacent to the other end 9c of the stage portion 9, and the wedge tool 35 is discharged onto the surface 17a of the lead 17 as shown in FIG. The other end of the wire 41 is joined.

At this time, in a state where the wire 41 is arranged in the guide groove 37a of the first flat surface 35b, the wedge tool is moved in the direction of the central axis L2, and the first flat surface 35b of the wedge tool 35 and the lead 17 are The other end of the wire 41 is sandwiched between the surface 17a. In this state, since the first flat surface 35b and the surface 17a of the lead 17 are arranged substantially in parallel, the wire 41 arranged in the guide groove 37a is connected to the surface 17a of the lead 17 by the first flat surface 35b. Can be pressed evenly. In this state, one end of the wire 41 is joined to the surface 17 a of the lead 17 by applying heat or ultrasonic vibration.
Thereafter, as shown in FIG. 6B, the wedge tool 35 is separated from the surface 17 a of the lead 17 while discharging the wire 41 from the wedge tool 35. Finally, with the supply of the wire 41 from the insertion hole 39 stopped, the wedge tool 35 is further separated from the surface 17a of the lead 17, whereby the wire 41 is cut and the bonding pad 29 of one magnetic sensor chip 5 is cut. And the electrical connection between the lead 17 is completed.

  After the wires 41 are arranged between one magnetic sensor chip 5 and each lead 17, each bonding pad 27 and each lead 17 of the other magnetic sensor chip 3 are electrically connected by the wires 41 in the same manner as described above. Connecting. When this electrical connection is made, the wedge tool is rotated by 180 ° about the central axis L2 in advance so that the second flat surface 35c is substantially parallel to the surface 3a of the other magnetic sensor chip 3. Keep it.

In the wiring process described above, the wedge tool 35 is translated with respect to the base 33 while discharging the wire 41 from the wedge tool 35 while maintaining the longitudinal direction of the guide grooves 37a and 37b perpendicular to the axis L1. .
For this reason, as shown in FIG. 7, when the relative positions of the bonding pads 27 and 29 and the leading end portion 17c of the lead 17 connected to the bonding pads 27 and 29 are shifted from each other with respect to the longitudinal direction of the guide grooves 37a and 37b. That is, when the arrangement direction of the bonding pads 27 and 29 and the tip 17c of the lead 17 is not perpendicular to the axis L1, but is inclined, the bonding pads 27 and 29 and the tip 17c of the lead 17 The wedge tool 35 is not moved linearly between them. That is, in this case, the wedge tool 35 matches the paths I and J in the figure orthogonal to the axis L1 in the vicinity of the bonding pads 27 and 29 and the surface 17a of the lead 17 so that no stress is generated in the wire. It is moved in the longitudinal direction of the guide grooves 37a and 37b.

  Here, the stress generated in the wire is different from the movement direction of the wire in the guide grooves 37a and 37b and the movement direction of the wedge tool 35, so that the wire arranged in the guide grooves 37a and 37b and the guide groove 37a , 37b and the wire extending outward of the wedge tool 35 are bent together and generated. Since both ends of the wire are bonded to the bonding pads 27 and 29 and the tip 17c of the lead 17, the wire in the guide grooves 37a and 37b is adjacent to the bonding pads 27 and 29 and the tip 17c of the lead 17. If the moving direction is different from the moving direction of the wedge tool 35, the stress described above becomes particularly large.

  At a position away from the vicinity of the bonding pads 27 and 29 and the surface 17a of the lead 17, the wedge tool 35 is moved obliquely so as to match the path K in the drawing connecting the paths I and J. This oblique movement can be performed at positions away from the bonding pads 27 and 29 from the magnetic sensor chips 3 and 5 and the surfaces 3a, 5a and 17a of the leads 17, so that in this movement, guide grooves Even if the moving direction of the wire in 37a and 37b differs from the moving direction of the wedge tool 35, no stress is generated in the wire.

  After completion of the wiring process, the lead frame 1 is removed from the bonding apparatus 31, and the lead frame 1 is sandwiched between the pair of molds E and F as shown in FIG. One mold E has a flat surface E1, and a rectangular frame portion 15 and leads 17 are arranged on the flat surface E1. The other mold F is formed with a plurality of recesses F2 that are recessed from the surface F1, and when the rectangular frame portion 15 of the lead frame 1 is sandwiched between the pair of molds E and F, the magnetic sensor chip 3, 5 and the stage portions 7 and 9 and the leads 17 of each lead frame 1 are accommodated in the recess F2.

Thereafter, the molten resin is injected into a resin forming space defined by the recesses F2 and the flat surface E1 of the molds E and F to form a resin mold portion that fills the magnetic sensor chips 3 and 5 in the resin (molding process). ).
In this molding process, since the entire stage portions 7 and 9 are arranged so as to be shifted in the thickness direction of the metal thin plate with respect to the rectangular frame portion 15, the molten resin is disposed on the back surfaces 7 d and 9 d of the stage portions 7 and 9. As a result, the gap between the back surfaces 7d and 9d of the stage portions 7 and 9 and the flat surface E1 of the mold E can be easily filled with the molten resin.

By performing the molding process described above, as shown in FIGS. 9 and 10, the magnetic sensor chips 3 and 5 are fixed inside the resin mold portion 49 in an inclined state. The resin used here is preferably a material having high fluidity so that the inclination angle of the magnetic sensor chips 3 and 5 does not change due to the flow of the resin.
Finally, the rectangular frame portion 15 is cut off to cut the connecting lead 13 and the lead 17 individually, and the manufacture of the magnetic sensor 50 is completed.

  The resin mold part 49 of the magnetic sensor 50 manufactured as described above is formed in a substantially rectangular shape in plan view similar to the rectangular frame part 15 described above. Each lead 17 is electrically connected to the magnetic sensor chips 3 and 5 by a metal wire 41, and the back surface 17 b is exposed on the lower surface 49 a side of the resin mold portion 49.

  The magnetic sensor chips 3 and 5 are embedded in the resin mold portion 49 and are inclined with respect to the lower surface 49 a of the resin mold portion 49. Further, the one end portions 3b and 5b of the magnetic sensor chips 3 and 5 facing each other face the upper surface 49c side of the resin mold portion 49, and the surfaces 3a and 5a are inclined at an acute angle. Here, the acute angle indicates an angle θ formed by the front surface 7a of the stage portion 7 and the back surface 9d of the stage portion 9.

The magnetic sensor chip 3 is sensitive to magnetic components in two directions of an external magnetic field, and these two sensitive directions are directions orthogonal to each other along the surface 3a of the magnetic sensor chip 3 (A direction and B). Direction).
The magnetic sensor chip 5 is sensitive to magnetic components in two directions of an external magnetic field, and these two sensitive directions are directions orthogonal to each other along the surface 5a of the magnetic sensor chip 5 (C direction and D direction).
Here, the A and C directions are parallel to the axis L1 of the stage portions 7 and 9, and are opposite to each other. The B and D directions are orthogonal to the axis L1 and are opposite to each other.

Furthermore, a plane defined by the A and B directions along the surface 3a of the magnetic sensor chip 3 (AB plane) and a plane defined by the C and D directions along the surface 5a of the magnetic sensor chip 5 (C -D plane) intersect each other at an acute angle θ.
Note that the angle θ formed by the AB plane and the CD plane is greater than 0 ° and not greater than 90 °. Theoretically, if the angle is greater than 0 °, the orientation of the three-dimensional geomagnetism Can be measured. However, in order to detect the geomagnetic vector component in the direction perpendicular to the AB plane or the CD plane with a sensitivity of a minimum level or more and to calculate the geomagnetic vector so as to reduce the error, the angle θ is set to 20 ° or more. It is preferable to set the angle to 30 ° or more in order to further reduce the error.
For example, the magnetic sensor 50 is mounted on a substrate in a mobile terminal device (not shown). In this mobile terminal device, the direction of geomagnetism measured by the magnetic sensor 50 is shown on the display panel of the mobile terminal device.

According to the manufacturing method of the bonding apparatus 31 and the magnetic sensor 50 described above, when the magnetic sensor chips 3 and 5 and each lead 17 are electrically connected by the wire 41, both ends of the wire 41 are connected to the wedge tool 35. The two flat surfaces 35 b and 35 c are uniformly pressed against the bonding pads 27 and 29 of the magnetic sensor chips 3 and 5 and the surface 17 a of the lead 17. Therefore, the bonding force between the bonding pads 27 and 29 and the surface 17a of the lead 17 and the wire 41 can be improved.
Moreover, since it is not necessary to form the bonding pads 27 and 29 of the magnetic sensor chips 3 and 5 large in order to improve the bonding force as in the prior art, the magnetic sensor chips 3 and 5 and the magnetic sensor 50 can be downsized. Can also be planned.

When bonding the wire 41 to the bonding pads 27 and 29 and the surface 17a of the lead 17, the wire 41 can be reliably disposed on the flat surfaces 35b and 35c of the wedge tool 35. It can be pressed against the surfaces of the pads 27 and 29 and the leads 17.
Further, since the position of the wire 41 with respect to the flat surfaces 35b and 35c of the wedge tool 35 is determined by the guide grooves 37a and 37b, the positioning of the wire 41 with respect to the bonding pads 27 and 29 and the surface 17a of the lead 17 can be easily performed. it can.

  When the wedge tool 35 is moved between the magnetic sensor chips 3 and 5 and the lead 17, the movement direction of the wedge tool 35 is matched with the longitudinal direction of the guide grooves 37 a and 37 b, so that the wire 41 is guided to the guide grooves 37 a and 37 b. Even if it moves along the longitudinal direction with respect to 37b, since it can prevent that stress generate | occur | produces in the wire 41, damage to the wire 41 can be prevented.

In the above embodiment, each wire 41 is bonded to the bonding pad 27, 29 and then bonded to the surface 17a of the lead 17. However, after bonding to the surface 17a of the lead 17, the bonding pad 27, 29 may be joined. That is, for example, one end of the wire 41 is bonded to the surface 17a of the lead 17 using the first flat surface 35c of the wedge tool 35, and then the bonding pad 27, 29 may be joined to the other end of the wire 41.
Further, although the wedge tool 35 is configured by providing the guide grooves 37a and 37b on the flat surfaces 35b and 35c, the wedge tool 35 is not limited to this and may be arranged at least substantially parallel to the surface 17a of the lead 17. The first flat surface 35b that can be formed and the second flat surface 35c that can be disposed substantially parallel to the surfaces 3a and 5a of the inclined magnetic sensor chips 3 and 5 may be provided.

Furthermore, although the stage tilting process is performed after the lead frame 1 preparation process, the stage tilting process is not limited to this and may be performed simultaneously with the lead frame 1 preparation process.
In addition, although the bonding process is performed after the stage tilting process, the present invention is not limited to this, and the stage tilting process may be performed after the bonding process.

Furthermore, in the bonding process, the magnetic sensor chips 3 and 5 are bonded to the surfaces 7a and 9a of the stage portions 7 and 9 via the silver paste. However, the present invention is not limited to this. 9 may be adhered.
In the above embodiment, the lead frame 1 including the two stage portions 7 and 9 has been described. However, the present invention is not limited to this, and the lead frame 1 may be applied to a lead frame including one or three or more stage portions. Good. That is, you may apply to the manufacturing method of a magnetic sensor provided with the magnetic sensor chip | tip of 1 or 3 or more, and the bonding apparatus used for manufacture of this magnetic sensor.

Furthermore, although the frame portion 11 includes the rectangular frame portion 15 formed in a substantially rectangular frame shape in plan view, the frame portion is not limited to this, and the frame body portion projects the lead 17 at least inward. As long as it has. That is, this frame part may be formed in a circular shape in a plan view, for example, and may have a three-dimensional structure.
Further, the stage portions 7 and 9 are formed in a substantially rectangular shape in plan view, but the present invention is not limited to this, and at least the magnetic sensor chips 3 and 5 are formed so as to be capable of being bonded to the surfaces 7a and 9a. That's fine. That is, the stage portions 7 and 9 may be formed in, for example, a circular shape or an oval shape in a plan view, or may be provided with holes penetrating in the thickness direction or formed in a mesh shape. .

Furthermore, the magnetic sensor chips 3 and 5, the leads 17, and the stage portions 7 and 9 are integrally fixed by the resin mold portion 49, but the present invention is not limited to this. For example, in the internal space of the box as a package The magnetic sensor chips 3 and 5, the leads 17, and the stage portions 7 and 9 may be accommodated and fixed integrally.
In the embodiment of the present invention, the description is applied to a magnetic sensor that detects a magnetic direction in a three-dimensional space. However, the present invention is not limited to this, and a physical quantity sensor that measures at least the azimuth and orientation in a three-dimensional space. If it is. Here, the physical quantity sensor may be, for example, an acceleration sensor equipped with an acceleration sensor chip that detects the magnitude and direction of acceleration instead of the magnetic sensor chip.

  As mentioned above, although embodiment of this invention was explained in full detail with reference to drawings, the concrete structure is not restricted to this embodiment, The design change etc. of the range which does not deviate from the summary of this invention are included.

It is a top view which shows the lead frame used for the manufacturing method of the magnetic sensor which concerns on one Embodiment of this invention. FIG. 2 is a side sectional view showing a state in which a stage tilting step and an adhesion step are performed on the lead frame of FIG. It is a schematic sectional side view which shows the bonding apparatus which concerns on one Embodiment of this invention. It is a principal part expanded sectional view which shows the front-end | tip part of the wedge tool of the bonding apparatus of FIG. 4, and an enlarged plan view. It is an expanded sectional view which shows the method of joining a wire to a magnetic sensor chip with the bonding apparatus of FIG. It is an expanded sectional view which shows the method of joining a wire to a lead with the bonding apparatus of FIG. 4, (a) has shown the state which pressed down the end of the wire on the surface of the lead, (b) is (a ) Shows a state where the wedge tool is separated from the surface of the lead. It is a schematic plan view which shows the movement path | route of the wedge tool from a bonding pad to a lead | read | reed. It is an expanded sectional view which shows the formation method of a resin mold part. It is a top view which shows the magnetic sensor manufactured with the lead frame of FIG. It is sectional drawing which shows the magnetic sensor manufactured with the lead frame of FIG. It is a side view which shows the state which carried out the wire bonding of the conventional magnetic sensor.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Lead frame, 3, 5 ... Magnetic sensor chip (physical quantity sensor chip), 3a, 5a ... Surface, 7, 9 ... Stage part, 7a, 9a ... Surface, 11 ... -Frame part, 17 ... Lead, 17a ... Surface, 31 ... Bonding device, 33 ... Base, 35 ... Wedge tool, 35b ... First flat surface, 35c ... -2nd flat surface, 37a, 37b ... guide groove, 41 ... wire, 50 ... magnetic sensor (physical quantity sensor)

Claims (4)

A stage portion having a stage portion on which a physical quantity sensor chip is placed and a frame portion having a plurality of leads disposed around the stage portion, and wherein the stage portion is inclined with respect to the frame portion, and the stage portion is used. A bonding apparatus for electrically connecting the physical quantity sensor chip placed on the lead and the leads to each other by a wedge bonding method,
A base on which the lead frame is disposed, and a wedge tool that is movably attached to the base and electrically connects the surface of each lead and the surface of the inclined physical quantity sensor chip with a wire;
The wedge tool is formed substantially parallel to the surface of the lead, and is formed substantially parallel to the surface of the physical quantity sensor chip, a first flat surface sandwiching the wire together with the surface of the lead, and the physical quantity sensor chip And a second flat surface sandwiching the wire together with the surface.   A guide groove that is recessed from the first flat surface and the second flat surface and that distributes the wire extends in a direction along each of the first flat surface and the second flat surface. The bonding apparatus according to claim 1.   The bonding apparatus according to claim 2, wherein the wedge tool is moved in the longitudinal direction of the guide groove at least in the vicinity of each surface of the lead and the physical quantity sensor chip. A preparation step of preparing a lead frame having a stage portion on which a physical quantity sensor chip is placed on the surface and a frame portion including a plurality of leads arranged around the stage portion;
A stage tilting step of tilting the stage part with respect to the frame part;
Bonding step of bonding the physical quantity sensor chip to the stage part;
A wiring step of electrically connecting the surface of each lead and the inclined surface of the physical quantity sensor chip with a wire by a wedge bonding method;
In the wiring step, each of the lead and the physical quantity sensor chip is arranged in a state in which a flat surface of a wedge tool used for the wedge bonding method is arranged substantially parallel to each surface of the lead and the physical quantity sensor chip. A method of manufacturing a physical quantity sensor, wherein the wire is sandwiched together with a surface.

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