JP4651763B2 - Semiconductor pressure sensor - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a semiconductor pressure sensor that detects a fluid pressure by a semiconductor pressure sensor element and outputs it as an electrical signal.
[0002]
[Prior art]
FIG. 4 is a longitudinal sectional view of the semiconductor pressure sensor 100 proposed in Japanese Patent Application No. 11-957 related to the applicant's prior application. The semiconductor pressure sensor 100 includes a semiconductor pressure sensor element 101 that is formed using a silicon semiconductor substrate and detects the pressure of a fluid to be measured; a ceramic sensor case 103 that houses the semiconductor pressure sensor element 101; and a semiconductor And a metal cylinder 105 that guides the fluid to be measured to the pressure sensor element 101.
[0003]
The semiconductor pressure sensor element 101 includes a diaphragm 107 in which a resistance bridge circuit (not shown) is formed, and a plurality of connection electrodes (not shown) that support the outer periphery of the diaphragm 107 and are connected to the resistance bridge circuit. ) Is formed integrally with the diaphragm support portions 109a and 109b.
[0004]
The sensor case 103 made of ceramic is provided with a fluid introduction hole 111 for guiding a fluid to be pressure-measured to the diaphragm portion 107 of the semiconductor pressure sensor element 101, and the diaphragm support portions 109a and 109b of the semiconductor pressure sensor element 101 on the upper surface. Includes a wall 113 fixed so as to surround one open end of the fluid introduction hole 111 and a peripheral wall 115 surrounding the semiconductor pressure sensor element 101 and integrated with the wall 113. A space surrounded by the peripheral wall portion 115 and the wall portion 113 constitutes an element housing recess 117.
[0005]
The cylindrical body 105 includes an annular flange portion 119 that extends toward the radially outer side of the cylindrical body 105 at the end on the sensor case 103 side. The flange portion 119 of the cylindrical body 105 is fixed by soldering to an annular soldered portion 121 formed on the back surface of the wall portion 113 so as to surround the other opening end portion of the fluid introduction hole 111. The details are described in Japanese Patent Application No. 11-957, and will be omitted.
[0006]
In the semiconductor pressure sensor 100, when a fluid to be measured is supplied to the fluid introduction hole 111 and the pressure of the fluid acts on the diaphragm portion 107 of the semiconductor pressure sensor element 101, the diaphragm portion 107 is physically caused by a difference from the atmospheric pressure. In response to this distortion, the resistance value of the resistance bridge circuit provided in the diaphragm unit 107 changes, and the change in resistance value is output as an electrical signal.
[0007]
[Problems to be solved by the invention]
Even the semiconductor pressure sensor with the previously proposed structure exhibits necessary and sufficient performance depending on the required accuracy. However, in this semiconductor pressure sensor 100, depending on the required accuracy, a change in temperature (temperature characteristic) appearing in the output accompanying a change in temperature of the fluid whose pressure is measured or a change in ambient temperature becomes a problem.
[0008]
As a result of the inventor's research, one of the causes that the temperature characteristics are deteriorated is that the metal cylinder 105 is soldered to the soldered portion formed on the back surface of the wall portion 113 of the sensor case 103. I understood. That is, the soldering portion formed between the flange portion of the cylinder and the soldered portion formed on the outer surface of the sensor case has a thermal expansion (linear expansion coefficient) of the cylinder caused by the temperature change of the fluid. Stress is generated from the difference from the thermal expansion (linear expansion coefficient) of the ceramic constituting the sensor case. This stress is applied to the ceramic sensor case, and further to the semiconductor sensor element fixed to the ceramic sensor case, and it has been found that this stress affects the output of the semiconductor sensor element. If the thickness of the wall 113 of the sensor case 103 is increased, the influence of such stress can be reduced. However, doing this not only increases the material cost of the sensor case and increases the price of the sensor, but also increases the height of the sensor.
[0009]
An object of the present invention is to provide a semiconductor pressure sensor having excellent temperature characteristics.
[0010]
Another object of the present invention is to provide a semiconductor pressure sensor capable of improving temperature characteristics without increasing the thickness of a wall portion of a sensor case to which a metallic cylinder is soldered and connected.
[0011]
[Means for Solving the Problems]
A semiconductor pressure sensor according to the present invention includes a diaphragm portion in which a resistance bridge circuit is formed and a diaphragm support portion that integrally supports an outer peripheral portion of the diaphragm portion, and a diaphragm of the semiconductor pressure sensor element on the surface. A ceramic sensor case having a wall portion in which a support portion is joined and a fluid introduction hole is formed in the diaphragm portion of the semiconductor pressure sensor element for introducing a fluid to be subjected to pressure measurement, and a wall portion of the sensor case. A solderable portion formed on the back surface so as to surround the periphery of the opening end portion of the fluid introduction hole and capable of being soldered; and a metal cylinder connected to the soldered portion by soldering. A semiconductor pressure sensor is an object of improvement.
[0012]
In the present invention, the flange portion is not provided at the annular soldering end of the metal cylinder to be soldered to the soldered portion. Then, the end face of the soldering end portion without the flange portion is soldered to the soldered portion. In this case, compared with the case where the flange portion is provided, the area of the soldering portion for soldering and connecting the soldered portion formed on the back surface of the wall portion of the sensor case and the soldering end portion of the cylindrical body is reduced. Get smaller. As a result, due to the difference between the thermal expansion (linear expansion coefficient) of the cylinder caused by the temperature change of the fluid or the surrounding temperature and the thermal expansion (linear expansion coefficient) of the ceramic constituting the sensor case, The generated stress is reduced. In the present specification, solder refers to a bonding material that melts when heated and has a function of bonding metals together when cooled naturally.
[0013]
Even when the cylindrical body is soldered and connected without providing the flange portion, if the thickness of the wall portion of the sensor case becomes thin, the influence of the stress generated in the soldered portion appears in the output. Therefore, assuming that the soldered portion formed on the back surface of the wall of the sensor case has a circular shape having a predetermined width dimension, the mounting position of the cylinder and the mounting position of the semiconductor pressure sensor element are as follows. It is preferable that the relationship be In other words, a virtual inscribed circle between the inscribed circle and the circumscribed circle of the soldered portion and a virtual center circle concentric with the circumscribed circle introduces fluid into the junction region between the diaphragm support portion and the sensor case wall. The position of the part to be soldered is determined so as to be located outside the virtual annular center line that is virtual so as to surround the hole. Here, the virtual annular center line is circular if the shape of the diaphragm support portion is annular, and is rectangular if the shape of the diaphragm support portion is rectangular, depending on the shape of the diaphragm support portion. The shape changes. In this case, a cylindrical body having a soldered end portion having a center diameter equal to or larger than the virtual center circle is used. Here, the center diameter is a diameter of an imaginary circle that is hypothesized at the center between the inner peripheral surface and the outer peripheral surface of the soldered end of the cylinder and is concentric with the inner peripheral surface and the outer peripheral surface. The soldering end of the cylinder is soldered to the soldered part so as to be substantially concentric with the virtual center circle. This makes it difficult for the stress applied to the sensor case from the soldered portion of the soldered portion to be applied to the semiconductor sensor element. The further away the virtual center circle is from the virtual center line, the more the influence of stress on the semiconductor sensor element can be reduced.
[0014]
In particular, when the soldered part is partially opposed to the joining region with the wall in between, the thickness of the wall part between the joining region and the soldered part is 2.5 mm or less. The thickness of the soldered end of the cylinder is in the range of 0.2 to 0.8 mm. If it does in this way, the thickness of a wall part can be made thin, and the soldering intensity | strength required for fixation of a cylinder can be ensured, without enlarging the area of a soldering part too much.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an example of an embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1A is a partially cutaway plan view of an embodiment of a semiconductor pressure sensor of the present invention, and FIG. 1B is a cross-sectional view taken along the line BB of FIG. FIG. 2 is a view showing the back surface of the sensor case before soldering and connecting a cylindrical body 31 to be described later.
[0016]
The semiconductor pressure sensor 1 according to the present embodiment basically includes a semiconductor pressure sensor element 3 that detects fluid pressure, a ceramic sensor case 5 that supports the semiconductor pressure sensor element 3, and a cylinder 31 that will be described later. It is provided as a configuration requirement. The semiconductor pressure sensor element 3 includes a diaphragm portion 9 in which a bridge circuit 7 including diffusion resistors R1, R2, R3, and R4 as shown in FIG. 3 is formed, and a diaphragm support portion 11a that supports the outer peripheral portion of the diaphragm portion 9. , 11b and has a structure that is integrally molded. The diaphragm portion 9 of the semiconductor pressure sensor element 3 is a silicon diaphragm formed by etching a rectangular silicon wafer, and the diaphragm support portion 11 is formed by forming the diaphragm portion 9. The surface of the diaphragm portion 9 is covered with a protective insulating film 13 after the diffusion resistors R1 to R4 are formed.
[0017]
The sensor case 5 includes a wall portion 17 and a peripheral wall portion 19 to which an annular diaphragm support portion 11a of the semiconductor pressure sensor element 3 is joined. The wall portion 17 is formed with a fluid introduction hole 15 for guiding a fluid to be subjected to pressure measurement to the diaphragm portion 9 of the semiconductor pressure sensor element 3, and the annular diaphragm support portion 11 is formed of the fluid introduction hole 15. It joins to the surface of the wall part 17 so that one opening edge part may be enclosed. The peripheral wall 19 has a shape surrounding the semiconductor pressure sensor element 3, and the opening of the peripheral wall 19 is closed by a metal lid plate 20.
[0018]
The annular diaphragm support portion 11 of the semiconductor pressure sensor element 3 is cured so that no separation occurs between the linear support coefficient of the diaphragm support portion 11 and the linear expansion coefficient of the wall portion 17 even if there is a large difference. However, it is fixed to the bonding region 21 on the wall portion 17 by using a gel-like adhesive having flexibility. Further, the contour shape of the peripheral wall portion 19 of the sensor case 5 has a substantially rectangular shape having four corner portions.
[0019]
Such a sensor case 5 includes a first case component 23 including a wall portion 17, and a lower surface joined to an upper surface of the first case component 23 to form a remaining portion of the peripheral wall portion 19 and a first inner portion. It is comprised by the 2nd case structural part 25 formed so that a part of upper surface of 1 case structural part 23 might be exposed. The lid plate 20 is joined to the second case component 25.
[0020]
As shown in FIG. 3, the back surface of the first case component 23 constituting the wall portion 17 has a circular shape having a predetermined width dimension so as to surround the other opening end portion of the fluid introduction hole 15. A soldered portion 29 having a shape and a plurality of electrodes 30 are formed. The circular soldered portion 29 and one electrode 30 are connected via a connection pattern. The soldered portion 29 and the electrodes 30 are composed of a tungsten underlayer, a Ni undercoat layer, and an Au surface plating layer. And this to be soldered portion 29, the semiconductor pressure sensor element 3 of the diaphragm 9 to the pressure annular end portion of the metallic cylindrical body 31 of electrically Kutame through the fluid introduction hole 15 a fluid to be measured An end face of 33 (soldering end) is soldered and connected by solder 35. The width dimension of the metal thin film forming the annular soldered portion 29 is determined within a range in which the soldering strength is not significantly reduced. A fluid introduction path 37 communicating with the fluid introduction hole 15 is formed inside the cylindrical body 31.
[0021]
In this example, the soldered portion 29 formed on the back surface of the wall portion 17 constituted by the first case component 23 is virtually between the inscribed circle 39 and the circumscribed circle 41 of the soldered portion 29. A virtual center circle 43 concentric with the inscribed circle 39 and the circumscribed circle 41 is located outside the virtual annular center line CL surrounding the fluid flow hole 15 virtually in the joint region 21 between the diaphragm support portion 11 and the wall portion 17. It is formed to do. The annular soldering end 33 of the cylindrical body 31 has a center diameter that is the same as or larger than the virtual center circle 43. The cylindrical body 41 is soldered to the soldered portion 29 so that the soldering end portion 33 is substantially concentric with the virtual center circle 43. In the case of soldering connection, the cream solder is printed on the soldered portion 29 and dried, and then the end portion 33 of the cylindrical body 1 is placed thereon, and these are heated in a furnace to be cream solder. After melting, let it cool naturally.
[0022]
As in this example, when the soldered portion 29 partially faces the bonding region 21 with the wall portion 17 therebetween, the thickness dimension of the wall portion is reduced to a value of 2.5 mm or less. It is possible. In this case, the thickness of the end portion 33 (soldering end portion) of the cylindrical body 31 is preferably set to 0.2 to 0.8 mm. When the semiconductor pressure sensor element becomes large, the soldered portion 29 is formed so that the virtual center circle 43 is always located outside the virtual annular center line CL. The further away the virtual center circle 43 is from the virtual annular center line CL, the less the influence of the stress generated by the temperature change on the soldered portion of the cylindrical body 31 can be reduced.
[0023]
The sensor case 5 is connected to a required connecting electrode among a plurality of connecting electrodes 45 (not shown in the right half of the drawing) provided on the semiconductor pressure sensor element 3 by bonding wires 51. A plurality of case-side connection electrodes 47 are formed. The case side connection electrodes 47 are composed of a tungsten underlayer, a Ni undercoat layer, and an Au surface plating layer. These case side connection electrodes 47 are formed on the upper surface portion of the first case component 25 exposed inside the second case component 25.
[0024]
The outer surface of the peripheral wall 19 of the sensor case 5 is connected to a plurality of case-side connection electrodes 47 on the upper surface of the first case component 25 located below the second case component 25. A plurality of conductive lead patterns 49 (not shown in FIG. 1 (A)) are formed. The plurality of conductive lead patterns 49 are formed by extending a tungsten underlayer constituting the case side connection electrodes 47. A plurality of external connection electrodes 53a to 53h and a plurality of external connections are respectively connected to the lower surface of the first case component 23 and the upper surface of the second case component 25, respectively. The electrodes 30 are respectively formed. Further, the outer peripheral surface of the peripheral wall portion 19 of the sensor case 5 extends in the stacking direction in which the first and third case components 23 and 25 are stacked, opens on both sides in the stacking direction, and is orthogonal to the stacking direction. A plurality of grooves C1 to C8 that open in a direction away from the outer peripheral surface are formed. In particular, the groove portions C1, C2, C3, and C4 are respectively formed at four corners of the peripheral wall portion 19 that forms a substantially rectangular shape of the sensor case 5. The outer end portions of the plurality of conductive lead patterns 49 are exposed in the corresponding groove portions C1 to C8, respectively.
[0025]
Among the plurality of external connection electrodes 53a to 53h, 30..., The plurality of external connection electrodes 53a to 53d belonging to the first group formed on the lower surface of the first case component 23 and the second case component. The plurality of external connection electrodes 55a to 55d belonging to the second group formed on the upper surface of 25 are formed adjacent to the openings on both sides in the stacking direction of the plurality of groove portions C1 to C8, respectively. Within these groove portions C1 to C8, a plurality of external connection electrodes 53a to 53h that are paired on the outer end portions of the conductive lead patterns 49 ... exposed inside these groove portions and on both sides in the stacking direction of these groove portions. , 55a to 55h are electrically connected by a plurality of connection conductive patterns 49 provided along the groove portions.
[0026]
In the semiconductor pressure sensor 1 having the above-described structure, the fluid to be measured is supplied from the fluid introduction path 37 of the cylindrical body 31 to the fluid introduction hole 15. When the pressure of the fluid acts on the diaphragm portion 9 of the semiconductor pressure sensor element 3, a physical distortion occurs in the diaphragm portion 9 due to a difference from the atmospheric pressure, and a resistance bridge provided in the diaphragm portion 9 according to the distortion. The resistance value of the circuit 7 changes, and this change in resistance value is taken out as an output. If there is a change in temperature, stress is applied to the soldered portion 29 that is the joint between the sensor case 5 and the cylinder 31 due to the difference in thermal expansion coefficient between the ceramic sensor case 5 and the metal (brass) cylinder 31. Will occur. In the semiconductor pressure sensor 1 of this example, the soldered end of the cylinder 31 does not have a flange, and the virtual center circle 43 of the cylinder 31 is outside the virtual annular center line CL of the diaphragm support 11. Since the cylindrical body 31 is soldered and connected to the soldered portion 29 so as to be located at the position of the sensor case 5, the stress generated in the soldered portion is reduced and the stress generated in the soldered portion is reduced to the wall of the sensor case 5. Transmission to the semiconductor pressure sensor element 3 via the part 17 can be suppressed. As a result, according to the present invention, the temperature characteristics are greatly improved.
[0027]
【The invention's effect】
According to the present invention, since the flange portion is not provided in the metal cylinder that is soldered and connected to the soldered portion on the back surface of the wall portion of the ceramic sensor case, the soldered portion and the cylinder are soldered. The soldering part connecting the end part becomes smaller, and the stress generated in the soldering part can be reduced. Therefore, even if the thickness of the wall portion of the sensor case to which the cylindrical body is joined is reduced, the stress generated in the soldering portion due to the temperature change hardly reaches the semiconductor pressure sensor element, and the temperature characteristics can be improved.
[0028]
In particular, a virtual center circle concentric with the inscribed circle and the circumscribed circle between the inscribed circle and the circumscribed circle of the soldered portion is arranged between the diaphragm support portion and the sensor case wall. Formed so as to be positioned outside the virtual virtual center line so as to surround the fluid introduction hole in the joining region, and the soldered end of the cylinder as a center diameter is the same as or larger than the virtual center circle If the soldered end of the cylinder is soldered and connected to the soldered part so that it is arranged almost concentrically with the virtual center circle, the effect of the stress generated in the soldered part is greatly reduced. can do.
[Brief description of the drawings]
FIG. 1A is a partially cutaway plan view of an embodiment of a semiconductor pressure sensor of the present invention, and FIG. 1B is a cross-sectional view taken along line BB in FIG. 1A.
FIG. 2 is a bottom view of the sensor case before the cylinder is soldered to the sensor case in the embodiment of FIG.
FIG. 3 is a circuit diagram of a bridge circuit formed in a diaphragm portion of the semiconductor pressure sensor according to the embodiment of the present invention.
FIG. 4 is a longitudinal end view of a structure of an example of a conventional semiconductor pressure sensor.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Semiconductor pressure sensor 3 Semiconductor pressure sensor element 5 Sensor case 9 Diaphragm part 11, 11a, 11b Diaphragm support part 15 Fluid introduction hole 17 Wall part 19 Peripheral wall part 21 Joining area 29 Soldering part 31 Cylindrical body 33 Soldering end part 35 Solder 37 Fluid introduction path 39 Inscribed circle 41 circumscribed circle 43 Virtual center circle CL Virtual annular center line

Claims (2)

A semiconductor pressure sensor element in which a diaphragm portion in which a resistance bridge circuit is formed and a diaphragm support portion that supports an outer peripheral portion of the diaphragm portion are integrally formed;
A ceramic having a wall portion on which a diaphragm supporting portion of the semiconductor pressure sensor element is bonded and a fluid introduction hole is formed in the diaphragm portion of the semiconductor pressure sensor element to guide a fluid to be measured. A sensor case made of
A solderable portion capable of being soldered so as to surround the periphery of the opening end portion of the fluid introduction hole on the back surface of the wall portion of the sensor case;
A semiconductor pressure sensor comprising a metal cylinder connected to the soldered portion by soldering,
The annular soldering end of the cylindrical body to be soldered to the soldered portion does not include a flange portion, and the end surface of the soldering end is soldered to the soldered portion ,
The soldered portion has a circular shape having a predetermined width dimension,
An imaginary center circle concentric with the inscribed circle and the circumscribed circle between the inscribed circle and the circumscribed circle of the soldered portion is within a junction region between the diaphragm support portion and the wall portion of the sensor case. The soldered portion is formed so as to be located outside the virtual annular center line that is virtual so as to surround the fluid introduction hole.
The soldering end of the cylindrical body has a center diameter that is the same as or larger than the virtual center circle, and the soldering end is disposed substantially concentrically with the virtual center circle. A semiconductor pressure sensor. The soldered portion is partially opposed to the joining region with the wall portion in between,
The thickness dimension of the wall part between the joining region and the soldered part is 2.5 mm or less,
2. The semiconductor pressure sensor according to claim 1 , wherein a thickness of the soldering end portion of the cylindrical body is 0.2 to 0.8 mm.

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