JP2013033057A - Flow sensor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a flow sensor having a membrane which is thin in thickness and high in destruction resistant pressure.SOLUTION: In a flow sensor, an opening part 43 of a silicon substrate is covered with a thin membrane 33. On the membrane 33, a sensing part 32 having a heater 81, a side thermal resistor 82 and a temperature-measuring resistor 83 is formed. In wiring patterns constituting the sensing part 32, a portion thereof almost vertically crossing with an opening edge is formed to have a width beyond 8 μm.

Description

  The present invention relates to a flow rate sensor in which a sensing portion is formed on a thin portion of a semiconductor substrate. For example, a flow rate used in an environment in which foreign matters such as solid particles are likely to collide, such as a flow rate sensor arranged in an intake manifold of an internal combustion engine. It can be applied to sensors.

  Conventionally, a thermal flow sensor is known as this type of flow sensor. The flow sensor includes a silicon substrate, a hollow portion penetrating the front and back surfaces of the silicon substrate, a membrane (also referred to as a diaphragm) that covers the opening on the substrate surface side of the hollow portion, and a sensing unit disposed on the membrane With. The sensing unit includes a film heater and a temperature measuring resistor for measuring the temperature of the heater. Then, the heater is heated to a constant temperature, and the flow rate of the gas passing through the sensing unit is measured based on the amount of current that flows through the heater to keep the heater at a constant temperature.

  By the way, what has a sensing part on the membrane of a semiconductor substrate like said flow sensor, so that detection sensitivity improves, so that the thickness of a membrane is thin. For this reason, it is necessary to set the thickness of the membrane thin. However, when the thickness is thin, the membrane is easily broken. Therefore, how to improve the breakdown pressure of the membrane without increasing the thickness of the membrane is a problem.

  Conventionally, for example, the one described in Patent Document 1 has been proposed for the purpose of improving the durability of the membrane. This is intended to absorb thermal stress concentrated on the membrane by forming a platinum protective part at the boundary between the membrane (diaphragm) and the semiconductor substrate (silicon substrate).

JP 2002-14070 (42nd paragraph, FIG. 2).

  Accordingly, an object of the present invention is to realize a flow sensor having a thin membrane having a high breakdown voltage.

  In order to achieve the above object, according to the present invention, a semiconductor substrate (31, 31) having a recess (41) formed on the back surface of the substrate and a wiring pattern (80) formed on the substrate surface is provided. 40), the bottom portion (33) of the recess is formed thin, and the sensing portion (32) of the wiring pattern is formed on the substrate surface of the bottom portion. Of the wiring pattern formed on the surface of the substrate, a portion (84) that intersects the edge (43a to 43j) of the bottom portion substantially perpendicularly is formed with a width exceeding 8 μm. 30) is used.

  According to the experiment conducted by the inventors of this application, the thickness of the wiring pattern on the bottom (membrane) intersecting with the edge of the bottom of the recess substantially perpendicularly is formed to a width exceeding 8 μm. It was found that a flow sensor having a thin bottom portion (membrane) with high breakdown pressure can be realized.

  According to a second aspect of the present invention, in the flow sensor (30) according to the first aspect, a planar shape of the bottom portion (33) viewed from the surface side is formed in a rectangular shape, and the sensing portion (32) The technical means that the angle formed between the extending direction of the wiring pattern (80) and the edge of the bottom is approximately 45 ° is used.

  Since the planar shape viewed from the front surface side of the bottom portion is formed in a rectangular shape, and the angle formed by the extending direction of the wiring pattern constituting the sensing portion and the edge of the bottom portion is approximately 45 °, the wiring pattern and the bottom side Can be non-parallel. Also, the wiring pattern can be separated from the bottom edge.

  According to a third aspect of the present invention, in the flow rate sensor (30) according to the first or second aspect, an edge (43a) other than the corner portion of the bottom portion of the wiring pattern formed on the substrate surface of the bottom portion. ˜43j) uses technical means that the part crosses the edge substantially perpendicularly.

  According to the experiment conducted by the inventors of this application, the wiring pattern on the bottom (membrane) so that the portion passing through the edge other than the corner of the bottom of the recess intersects the edge substantially perpendicularly. It has been found that a flow sensor having a bottom (membrane) that is thin and difficult to break can be realized by forming.

  According to a fourth aspect of the present invention, there is provided a semiconductor substrate (31, 40) in which a recess (41) is formed on the back surface of the substrate and a wiring pattern (80) is formed on the substrate surface, and the bottom of the recess In the flow rate sensor in which the sensing part (32) is formed on the substrate surface of the bottom part of the wiring pattern, the planar shape viewed from the surface side of the bottom part is 8 in the wiring pattern. The flow rate is formed in a square shape, and a portion of the wiring pattern formed on the substrate surface of the bottom portion that passes through an edge other than the corner portion of the bottom portion intersects the edge substantially perpendicularly. The technical means of sensor (30) is used.

  According to the experiment conducted by the inventors of this application, the bottom (membrane) is formed so that the planar shape seen from the surface side is an octagon, and the edges other than the corners of the bottom are substantially perpendicular to each other. It was found that a flow rate sensor having a bottom portion (membrane) having a small thickness and a high breakdown voltage can be realized by forming a wiring pattern.

  According to a fifth aspect of the present invention, in the flow sensor (30) according to any one of the first to fourth aspects, the semiconductor substrate (31, 40) includes a support substrate (40) made of silicon and , An SOI substrate comprising a silicon oxide film (50) formed on the surface of the support substrate and a silicon layer formed on the surface of the silicon oxide film, wherein the recess (41) is the back side of the support substrate The technical means is used in which the bottom (33) is made of the silicon oxide film and the wiring pattern (80) is made of the silicon layer.

  If an SOI (Silicon on Insulator) substrate is used, a concave portion having a thin bottom, a wiring pattern, and a sensing portion can be formed relatively easily. That is, if etching is performed from the back surface of the silicon support substrate to form a cavity that penetrates from the back surface of the support substrate to the front surface, the insulating film exposed to the opening on the front surface side of the cavity is formed at the bottom of the recess. Can be set. Further, by performing masking and photoetching on the surface of the silicon layer, a wiring pattern made of silicon can be formed.

  According to a sixth aspect of the present invention, in the flow rate sensor (30) according to the fifth aspect, the technical means that the crystal plane orientation in the thickness direction of the support substrate (40) is a (100) plane is used.

  Since the crystal plane orientation in the thickness direction of the support substrate is the (100) plane, a rectangular opening can be formed on the surface of the support substrate by anisotropically etching the support substrate from the back surface. The bottom (membrane) covering the opening can be rectangular.

  In the invention according to claim 7, in the flow sensor (30) according to claim 5, the technical means that the crystal plane orientation in the thickness direction of the support substrate (40) is the (110) plane is used.

  Since the crystal plane orientation in the thickness direction of the support substrate is the (110) plane, an octagonal opening can be formed in the surface of the support substrate by anisotropically etching the support substrate from the back surface. The bottom (membrane) covering the opening can be made octagonal.

  According to an eighth aspect of the present invention, in the flow sensor (30) according to any one of the fifth to seventh aspects, the crystal plane orientation in the thickness direction of the silicon layer is a (100) plane. Use technical means.

  Since the crystal plane orientation in the thickness direction of the silicon layer is the (100) plane, it is possible to reduce the resistance change of the sensing unit due to the piezoresistance effect or the hot carrier phenomenon when stress is applied to the bottom of the recess. Therefore, the detection accuracy can be increased.

  According to a ninth aspect of the present invention, in the flow rate sensor (30) according to any one of the fifth to eighth aspects, the crystal plane orientations in the thickness direction of the support substrate (40) and the silicon layer are different. The technical means is used.

  Since the crystal plane orientations in the thickness direction of the support substrate and the silicon layer are different, the arrangement direction of the bottom portion of the recess formed in the support substrate and the arrangement direction of the wiring pattern formed in the silicon layer on the substrate surface of the bottom portion should be different. Can do. For example, the arrangement relationship described in claim 3 can be obtained.

  According to a tenth aspect of the present invention, in the flow sensor (30) according to any one of the fifth to ninth aspects, a technical means is used in which the silicon layer is formed of single crystal silicon.

  A resistor, for example, a heater and a resistance temperature detector according to claim 13 can be formed by doping impurities into single crystal silicon.

  According to a twelfth aspect of the present invention, in the flow rate sensor (30) according to any one of the first to eleventh aspects, a portion where the wiring pattern is formed and a portion where the wiring pattern is not formed at the bottom. The technical means that a step is formed between the two is used.

  In a flow sensor in which a step is formed between a portion where the wiring pattern is formed and a portion where the wiring pattern is not formed at the bottom, the stress acting on the bottom is concentrated on the step, and the step There is a risk of cracking.

  In particular, as described in claim 10, when a flow sensor is manufactured using an SOI substrate in which the silicon layer is formed of single crystal silicon, the thickness of the silicon layer is 0 as described in claim 11. Since the thickness is 0.7 μm or more, a step formed between a portion where the silicon layer is present and a portion where the silicon layer is not present, that is, a portion where the sensing portion is formed and a portion where the sensing portion is not formed is increased.

  However, even in a structure having such a step, the stress concentrated on the step can be dispersed by using the invention according to any one of claims 1 to 11. A flow sensor having a bottom (membrane) having a small thickness and a high breakdown pressure can be realized.

  According to a thirteenth aspect of the present invention, in the flow sensor according to any one of the first to twelfth aspects, the sensing unit includes a heater and a resistance temperature sensor for measuring the temperature of the heater. And a technical means that outputs a signal corresponding to the gas flow rate is used.

When the sensing unit is a flow sensor that includes a heater and a resistance temperature sensor for measuring the heater temperature and outputs a signal corresponding to the gas flow rate, foreign matter such as solid particles in the gas is detected by the sensing unit. Used in an environment that is prone to collisions. For this reason, it is requested | required that the bottom part of a recessed part cannot be broken easily. On the other hand, in order to improve detection accuracy and detection speed, it is required that the bottom is thin.
That is, it is required to have a bottom portion that is thin but has a high breakdown voltage, but if the invention according to any one of claims 1 to 12 is used, the requirement can be satisfied.

  In addition, the code | symbol in each said parenthesis shows the correspondence with the specific means as described in embodiment mentioned later. Further, “substantially vertical” means including a substantially vertical state in addition to a completely vertical state.

It is perspective explanatory drawing which shows the cross section at the time of cut | disconnecting a part of flow sensor by the part of a membrane. It is a cross-sectional explanatory drawing which expands and shows the part of the membrane of the flow sensor shown in FIG. It is a top view of the sensing part which does not have a protection part in a membrane. It is a top view of the sensing part which has a protection part in a membrane. It is explanatory drawing of the apparatus used for verification of a prior art, (a) is the top view, (b) is AA arrow sectional drawing of (a). It is explanatory drawing which shows the relationship between the several measurement point of the membrane in which the level | step difference was formed, and the stress value in each measurement point. It is explanatory drawing which shows the relationship between the measurement point of the membrane in which the level | step difference is not formed, and the stress value in a measurement point. It is explanatory drawing which shows the area | region where stress became the maximum. It is explanatory drawing which shows the area | region where stress became the maximum. It is explanatory drawing which shows the arrangement | positioning relationship between the level | step difference of a membrane, and an opening edge. It is a graph which shows the relationship between the distance from the opening part 43 of the level | step difference 33c, and the stress which acts on the level | step difference 33c. It is explanatory drawing which shows the arrangement | positioning relationship between a wiring pattern and an opening edge. It is a graph which shows the relationship between the width | variety of the wiring pattern which cross | intersects the opening part 43 substantially perpendicularly, the position which cross | intersects the opening part 43 substantially perpendicularly, and the stress which acts on the level | step difference 33c. It is explanatory drawing which shows the arrangement | positioning relationship between a wiring pattern and an opening part. 10 is a graph showing the result of verification 5. It is a top view of the membrane in experiment. It is explanatory drawing of a cavity part, (a) is a back view of a cavity part, (b) is AA arrow sectional drawing of (a), (c) is BB arrow sectional drawing of (a). is there. It is a top view of the membrane with which the flow sensor of a 1st embodiment was equipped. It is explanatory drawing of the cavity part which comprises the membrane shown in FIG. 18, (a) is a back view of a cavity part, (b) is AA arrow sectional drawing of (a), (c) is (a). BB arrow sectional drawing, (d) is CC arrow sectional drawing of (a). It is a top view of the membrane with which the flow sensor of 2nd Embodiment was equipped. It is explanatory drawing of the cavity part which comprises the membrane shown in FIG. 20, (a) is a back view of a cavity part, (b) is AA arrow sectional drawing of (a), (c) is (a). It is BB arrow sectional drawing. It is a top view of the membrane with which the flow sensor of 3rd Embodiment was equipped.

<First Embodiment>
A first embodiment of the present invention will be described.
[Verification of conventional technology]
The inventor of this application compared the durability of the structure in which the protective part is provided on the membrane and the structure in which the protective part is not provided, like the flow sensor described in Patent Document 1.

(Membrane structure)
The general structure of the membrane will be described. FIG. 1 is a perspective explanatory view showing a cross section when a part of a flow sensor is cut at a membrane portion. FIG. 2 is an enlarged cross-sectional explanatory view showing a membrane portion of the flow sensor shown in FIG. In FIG. 2, the portion indicated by reference numeral 31 is drawn larger than the actual size for easy understanding of the structure.

  In this embodiment, the flow sensor 30 is manufactured using an SOI substrate. As shown in FIG. 2, the flow sensor 30 is formed of a silicon substrate 40, a silicon oxide film 50 formed on the surface of the silicon substrate 40, and a single crystal silicon layer formed on the surface of the silicon oxide film 50. A wiring pattern 80, a silicon oxide film 60 covering the wiring pattern 80, and a silicon nitride film 70 formed on the surface of the silicon oxide film 60 are provided.

  A cavity 41 is formed through the substrate surface of the silicon substrate 40, and the opening 43 (FIG. 1) on the substrate surface side of the cavity 41 has silicon oxide films 50, 60, a wiring pattern 80, and a silicon nitride film 70. It is covered with the membrane 33 which consists of. That is, the bottom 42 of the cavity 41 is formed by the membrane 33.

  In this embodiment, the silicon substrate 40 has a (100) plane orientation in the thickness direction. The thickness of the silicon substrate 40 is 500 μm, and the thickness of the wiring pattern 80 (single crystal silicon layer) is 1 μm. Of the membrane 33, the thickness of the portion where the wiring pattern 80 is formed is about 3 μm, and the thickness of the portion where the wiring pattern 80 is not formed is about 2 μm. That is, a step of about 1 μm is formed on the membrane 33 between a portion where the wiring pattern 80 is formed and a portion where the wiring pattern 80 is not formed.

  The cavity 41 is formed by performing anisotropic etching from the exposed portion of the back surface of the silicon substrate 40 using the silicon nitride film as a mask until the silicon oxide film 50 is exposed using an etchant such as KOH. At this time, since the plane direction of the thickness direction of the silicon substrate 40 is (100), as shown in FIG. 1, a cavity 41 is formed in which the four sides are surrounded by a tapered surface and the opening surface on the substrate surface side is rectangular. Is done.

(Structure of sensing part without protective part)
Next, the structure of the sensing part that does not have a protective part on the membrane will be described. FIG. 3 is a plan view of a sensing unit having no protective part on the membrane.

  The membrane 33 is formed with a sensing unit 32 for detecting the flow rate of the gas flowing on the surface of the membrane 33. The sensing unit 32 includes a heater 81, side heat resistors 82 and 82 formed on both sides of the heater 81, temperature measuring resistors 83 and 83 formed on both sides of each side heat resistor 82, and each temperature measuring resistor 83. A midpoint output unit 84. Each indirectly heated resistor 82 is used for temperature control of the heater 81. The temperature around the heater 81 is increased by the heat generated from the heater 81, a change in the temperature distribution is detected by each temperature measuring resistor 83, and the gas flow rate is measured based on the detection result.

  The wiring pattern 80 is made of a single crystal silicon layer and is formed in a thin film shape. The heater 81, the indirectly heated resistor 82, and the temperature measuring resistor 83 are part of the wiring pattern 80, and are formed by doping impurities into the single crystal silicon layer. The opening 43 is formed in a rectangular shape, and has an opening edge 43a and an opening edge 43b facing each other. The heater 81 and the side heat resistance 82 are disposed at substantially the center of the opening 43.

  Each temperature measuring resistor 83 is formed in a double U-shape and is arranged in parallel to the opening edge 43a. Further, each temperature measuring resistor 83 is electrically connected to the wiring portion 83a having a large area. Each wiring part 83a crosses the opening edge 43a and has a wiring side part 83b parallel to the opening edge 43a on the outside of the opening edge 43a. In the figure, the unhatched region is a region where the wiring pattern 80 is formed (a region composed of the single crystal silicon layer, the silicon oxide films 50 and 60, and the silicon nitride film 70), and the hatched region. Is a region where the wiring pattern 80 is not formed (region consisting of the silicon oxide films 50 and 60 and the silicon nitride film 70).

(Structure of sensing part with protective part)
Next, the structure of the sensing part which has a protection part in a membrane is demonstrated. FIG. 4 is a plan view of a sensing unit having a protective part on the membrane.

  Each wiring part 83a connected to each temperature measuring resistor 83 has an enlarged area compared to that shown in FIG. Each wiring side portion 83b of each wiring portion 83a extends over the opening edge 43a and extends to the inside of the opening portion 43. Each wiring side portion 83b is formed in parallel with the opening edge 43a. That is, the portion surrounded by the alternate long and short dash line in the figure is a reinforcing portion 83c formed for the purpose of increasing the breakdown pressure of the membrane 33.

(Verification of conventional technology)
Next, verification of the prior art will be described. 5A and 5B are explanatory views of the apparatus used for this verification. FIG. 5A is a plan view thereof, and FIG. 5B is a cross-sectional view taken along line AA in FIG.

  A plurality of cavities 41 are formed in the substrate 90 used for verification, and membranes 33 are formed in the openings 43 of the cavities 41, respectively. A space 91 communicating with each cavity 41 is formed inside the substrate 90. A filling port 92 for filling the space 91 with oil is formed on the side surface of the substrate 90.

  First, a substrate 90 having a plurality of membranes 33 having no protective part formed on the surface was prepared. Then, the space 91 was filled with oil from the filling port 92, the oil pressure inside the space 91 was increased, and the pressure applied to one membrane when any of the membranes 33 was broken was evaluated as the breakdown pressure. As a result, the breakdown pressure was 0.8 MPa.

Next, a substrate 90 having a plurality of membranes 33 having protective portions formed thereon was prepared, and the same evaluation as described above was performed. As a result, the breakdown pressure was 0.8 MPa.
That is, the breakdown voltage of the membrane 33 is the same regardless of whether or not it has a protective part. Therefore, it has been found that the breakdown voltage of the membrane 33 cannot be increased even when the wiring pattern 83 of the temperature measuring resistor 83 in the wiring pattern 80 is extended to the inside of the opening 43 to increase the area.

[Verification 1]
Therefore, the inventor presumed that the structure of the membrane 33 itself was related to the breakdown pressure of the membrane 33 and performed a new verification. FIG. 6 is an explanatory diagram showing a relationship between a plurality of measurement points of a membrane having a step and stress values at each measurement point. FIG. 7 is an explanatory diagram showing the relationship between the measurement point of the membrane where no step is formed and the stress value at the measurement point.

  As shown in FIG. 6, a step 33 c exists on the surface of the membrane 33 between a forming portion 33 a where the wiring pattern 80 is formed and a non-forming portion 33 b where the wiring pattern 80 is not formed. There are a plurality of steps 33c, ranging from a step 33c formed near the opening edge 43a of the silicon substrate 40 to a step 33c formed near the opening edge 43a.

Therefore, each step 33c is set to measurement points A to G, and the stress value at each measurement point when the center of the surface of the membrane 33 is pressed in the back direction is obtained by simulation of two-dimensional analysis.
As a result, as shown in FIG. 6, the stress values at the measurement points A to G were 3973 MPa, 8207 MPa, 12736 MPa, 9307 MPa, 5957 MPa, 4813 MPa, and 3709 MPa in this order. That is, it has been found that the stress value applied to each step 33 c is larger as it is closer to the opening edge 43 a and smaller as it is farther from the opening 43.

  On the other hand, as shown in FIG. 7, in the membrane 33 in which no step is formed, the stress value at the measurement point corresponding to the opening edge 43a was 4230 MPa. That is, it was found that the stress value at the measurement point C of the membrane 33 on which the step 33c was formed was smaller than 12736 MPa.

From the above, it has been found that the stress applied to the membrane 33 concentrates on the step 33 c near the opening edge 43 a of the silicon substrate 40.
Therefore, it has been found that the breakdown voltage of the membrane 33 may be increased by separating the step 33c from the opening edge 43a as much as possible.

[Verification 2]
Next, the inventor of this application verified the relationship between the layout relationship between the wiring pattern 80 and the opening 43 formed on the membrane 33 and the breakdown voltage of the membrane 33. 8 and 9 are explanatory diagrams showing regions where stress is maximized.

  The membrane 33 shown in FIG. 8 is formed in a rectangular shape having a width W of 450 μm and a length L of 700 μm. The breakdown pressure of the membrane 33 is 0.8 Mpa. As a result of pressing the center of the surface of the membrane 33 in the back direction, the value of the stress applied to the region 83d of the membrane 33 where the temperature measuring resistor 83 is formed is maximized. That is, in the membrane 33, the stress applied to the region 83d closest to the center of the opening edge 43a that is the longer edge of the opening 43 and parallel to the opening edge 43a is maximized. It became.

  The membrane 33 shown in FIG. 9 is formed in a substantially square shape having a width W of 450 μm and a length L of 500 μm. The breakdown pressure of the membrane 33 is 0.1 MPa. As a result of pressing the center of the surface of the membrane 33 in the back direction, the value of the stress applied to the region 83e where the midpoint output portion 84 of the temperature measuring resistor 83 is formed in the membrane 33 is maximized. That is, in the membrane 33, the stress applied to the region 83e closest to the center of the opening edge 43b, which is the shorter edge of the opening 43, and in which the wiring pattern parallel to the opening edge 43b is formed is maximum. It became.

From the above, it was found that the stress applied to the membrane 33 is concentrated in the regions 83d and 83e where the parallel wiring pattern is formed in the center of the opening edges 43a and 43b of the opening 43 of the silicon substrate 40.
Therefore, it was concluded that the breakdown voltage of the membrane 33 can be increased by separating the wiring pattern parallel to the center of the opening edges 43a and 43b as far as possible from the opening edge.

[Verification 3]
Next, the inventors of this application verified the relationship between the distance from the opening 43 of the step 33 c formed on the membrane 33 and the stress acting on the step 33 c. FIG. 10 is an explanatory diagram showing an arrangement relationship between the step of the membrane and the opening edge. FIG. 11 is a graph showing the relationship between the distance from the opening 43 of the step 33c and the stress acting on the step 33c.

  The membrane 33 used in this verification is a square having a width W of 700 μm and a length L of 700 μm. Moreover, the membrane 33 in which the step 33c parallel to each opening edge of the opening 43 was formed in four directions was used. And when the distance of the level | step difference 33c formed in the four sides of the membrane 33 and the opening part 43 is 0 micrometer, it verified about each in the case of 8 micrometers and 50 micrometers. Further, the stress at each measurement point on the membrane when the center of the surface of the membrane 33 was pressed toward the back surface with a force of 0.5 MPa was measured. The measurement point was set in a section parallel to the opening 43 between the steps facing each other. The distance between each measurement point is 0.1 mm.

  As a result of the verification, as shown in FIG. 11, the stress at each measurement point was the largest when the distance D between the step 33c of the membrane 33 and the opening 43 was 0 μm, and the stress was the smallest when the distance D was 50 μm.

From the above, it has been found that, of the step 33 c of the membrane 33, the stress concentrates on the step 33 c as the step 33 c parallel to the opening 43 approaches the opening 43.
Therefore, it was concluded that the breakdown voltage of the membrane 33 can be increased by reducing the wiring pattern parallel to the opening 43 as much as possible.

[Verification 4]
Next, the inventors verified the relationship between the width of the wiring pattern that intersects the opening 43 substantially perpendicularly and the stress at the step of the wiring pattern. Further, the relationship between the position where the wiring pattern intersects the opening 43 substantially perpendicularly and the stress at the step was also verified. FIG. 12 is an explanatory diagram showing the positional relationship between the wiring pattern and the opening edge. FIG. 13 is a graph showing the relationship between the width of the wiring pattern that intersects the opening 43 substantially perpendicularly, the position that intersects the opening 43 substantially perpendicularly, and the stress acting on the step 33c.

  The membrane 33 used in this verification is a square having a width W of 700 μm and a length L of 700 μm. Further, the membrane 33 in which the wiring pattern 85 that intersects the opening edges 43c and 43c of the opening 43 facing each other substantially perpendicularly is formed. When the line width ΔW of the wiring pattern 85 is 8 μm and the offset amount W1 from the center P of the edge 43c is 0 μm, the line width ΔW is 8 μm, and the offset amount W1 is 46 μm. Verification was performed for the case where the width ΔW was 100 μm and the offset amount W1 was 0 μm.

  Further, the stress at each measurement point on the membrane when the center of the surface of the membrane 33 was pressed toward the back surface with a force of 0.5 MPa was measured. The measurement point was set in a section passing through the center of the membrane 33 and parallel to the opening edge 43c. The distance between each measurement point is 0.1 mm.

  As a result of the verification, as shown in FIG. 13, it was found that as the line width ΔW of the wiring pattern 85 is thicker, the stress generated in the step of the wiring pattern 85 becomes smaller. It was also found that there was no significant difference in the stress generated in the step even if the offset amount W1 changed.

  From the above, it was concluded that the breakdown voltage of the membrane 33 can be increased by setting the line width ΔW of the wiring pattern 85 substantially perpendicular to the opening 43 to a width exceeding 8 μm.

[Verification 5]
Next, the inventors of this application verified the relationship between the wiring pattern obliquely intersecting the opening 43 and the stress at the step of the wiring pattern. The relationship between the position where the wiring pattern obliquely intersects the opening 43 and the stress at the step was also verified. FIG. 14 is an explanatory diagram showing the arrangement relationship between the wiring pattern and the opening. FIG. 15 is a graph showing the results of verification.

  The membrane 33 used in this verification is a square having a width W of 700 μm and a length L of 700 μm. Further, the membrane 33 in which the wiring pattern 86 that obliquely intersects the opening edges 43c and 43c facing each other of the opening 43 is used. Then, verification is performed with respect to the case where the line width ΔW of the wiring pattern 86 is 8 μm and the offset amount from the center P of the opening edge 43c is 0 μm, and when the line width ΔW is 8 μm and the offset amount is 196 μm. went.

  Further, the stress at each measurement point on the membrane when the center of the surface of the membrane 33 was pressed toward the back surface with a force of 0.5 MPa was measured. The measurement point was set in a section passing through the center of the membrane 33 and parallel to the opening edge 43c. The distance between each measurement point is 0.1 mm.

  As a result of the verification, as shown in FIG. 15, in the wiring pattern 86 that obliquely intersects with the opening edge 43c of the opening 43, the offset amount from the center P of the opening edge 43c is 0 μm, that is, with the center P of the opening edge 43c. The stress generated at the step of the wiring pattern 86 that crossed diagonally was the largest. In addition, the stress generated at the step of the wiring pattern 86 that obliquely intersects the opening edge 43c and has an offset amount of 196 μm was the second largest.

  FIG. 15 also shows a graph of a wiring pattern obtained in the above-described verification 5 that intersects the opening edge 43c substantially perpendicularly and has the same line width of 8 μm and an offset amount of 0 μm. Even when compared with the wiring pattern that intersects the opening edge 43c substantially perpendicularly, it can be seen that the stress generated at the step of the wiring pattern 86 that obliquely intersects the opening edge 43c is considerably large.

  From the above, it is concluded that the wiring pattern 86 that obliquely intersects with the opening 43 is configured so as not to be arranged at the center of the opening edge 43c of the opening 43 as much as possible, thereby increasing the breakdown voltage of the membrane 33. Obtained. That is, among the wiring patterns 86 that intersect the opening 43, the wiring pattern that passes through the opening edge other than the corner of the opening 43 intersects the opening edge substantially perpendicularly and passes through the corner of the opening 43. Is configured to intersect with the corner portion at an acute angle, whereby the breakdown pressure of the membrane 33 can be increased.

[Experiment]
The inventor of this application conducted an experiment on the breakdown voltage of the membrane using the flow sensor manufactured with reference to the verification result of verification 2 described above. As described above, in the case of the flow sensor having the structure shown in FIG. 8, it is known that stress concentrates on the region 83d where the temperature measuring resistor 83 is formed.

  Therefore, the inventor manufactured a flow sensor having a membrane structure shown in FIG. FIG. 16 is a plan view of the membrane. The membrane 33 shown in the figure has a width W of 550 μm and a length L of 700 μm. The distance W2 from the end of the temperature measuring resistor 83 which is the wiring pattern 80 parallel to the opening 43 to the opening edge 43a is 97 μm.

  Moreover, what was shown in FIG. 3 was used as a membrane which has the conventional wiring pattern. The membrane 33 shown in FIG. 3 has a width W of 450 μm and a length L of 700 μm. Further, the distance W2 from the end of the temperature measuring resistor 83 which is the wiring pattern 80 parallel to the opening 43 to the opening edge 43a is 50 μm.

  Also, the cavity corresponding to the membrane shown in FIGS. 16 and 3 has the structure shown in FIG. FIGS. 17A and 17B are explanatory diagrams of the cavity, where FIG. 17A is a rear view of the cavity, FIG. 17B is a cross-sectional view taken along the line AA in FIG. FIG. The silicon substrate 40 forming the cavity 41 has a crystal plane orientation in the thickness direction formed on the (100) plane. Further, the inclination angle θ1 of each inner wall surface 41a forming the hollow portion 41 is 54.7 °.

  The center of the surface of the membrane 33 was pressurized toward the back surface, and the applied pressure when the membrane 33 was broken was evaluated as the breakdown pressure. As a result, the breakdown pressure was 0.8 MPa for the conventional membrane shown in FIG. 3 and 2.0 MPa for the membrane shown in FIG.

That is, it was proved that the breakdown voltage of the membrane 33 can be increased by 2.5 times by separating the temperature measuring resistor 83 from the opening 43 by 97 μm.
Therefore, by disposing the wiring pattern parallel to the opening edge of the opening 43 beyond the conventional 50 μm from the opening edge, the breakdown voltage of the membrane 33 can be increased more than before.

  Further, since the crystal plane orientation in the thickness direction of the silicon substrate 40 is the (100) plane, by using anisotropic etching, as shown in FIG. 17, the cavity 41 is viewed from the substrate surface side. The planar shape can be rectangular. Furthermore, since the crystal plane orientation in the thickness direction of the single crystal silicon layer forming the wiring pattern 80 is the (100) plane, even when stress is applied to the membrane 33, the piezoresistance effect caused by the stress Since the occurrence of the hot carrier phenomenon can be suppressed, the detection accuracy of the gas flow rate can be increased.

  Next, a characteristic configuration of the present invention will be described. FIG. 18 is a plan view of the membrane provided in the flow sensor of this embodiment. FIG. 19 is an explanatory view of the cavity part that constitutes the membrane shown in FIG. 18, wherein (a) is a back view of the cavity part, (b) is a cross-sectional view taken along the line AA in (a), and (c) (A) BB arrow sectional drawing, (d) is CC arrow sectional drawing of (a).

  As shown in FIG. 18, an octagonal membrane 33 is formed by an opening 43 having an octagonal shape in plan view. As indicated by reference sign Q <b> 1, the wiring portion 83 a that is electrically connected to the temperature measuring resistor 83 intersects the opening edge 43 e other than the corner portion of the opening 43 substantially perpendicularly. Further, as indicated by reference numeral Q2, the wiring portion 82a that is electrically connected to the indirectly heated resistor 82 intersects the opening edge 43d other than the corner portion of the opening portion substantially perpendicularly. Furthermore, the wiring portion 81 a that is in conduction with the heater 81 intersects the opening edge 43 f other than the corner portion of the opening 43 substantially perpendicularly. In addition, each wiring portion that intersects the opening edge substantially perpendicularly is formed with a line width exceeding 8 μm.

  The silicon substrate 40 that forms the cavity 41 on the back surface of the membrane 33 is one in which the crystal plane orientation in the thickness direction is formed on the (110) plane. As shown in FIG. 19A, the cavity 41 is formed with tapered surfaces 41b, 41b, 41c, 41c and a vertical surface 41d therebetween as inner wall surfaces.

  The tapered surfaces 41c and 41c facing each other along the <100> crystal axis are crystal plane orientation (111) planes, and the inclination angle θ2 is 35.3 °. Further, the tapered surfaces 41b and 41b facing along the <111> crystal axis are crystal plane orientation (100) planes. The tapered surface 41b is formed continuously from the vertical surface 41e of the crystal plane orientation (111) plane. The vertical plane 41d is a crystal plane orientation (111) plane.

  The membrane 33 masks the silicon substrate 40 and is formed by anisotropic etching. The opening of the mask used for masking is a rhombus having a major axis in the <100> crystal axis direction and four sides in a direction perpendicular to the <111> crystal axis. Form a square. Then, when the back surface of the silicon substrate 40 is masked with the mask and anisotropic etching is performed from the back surface with an etchant such as KOH, a cavity 41 having an opening 43 having an octagonal shape in plan view is formed.

  As described above, by forming the opening 43 of the silicon substrate 40 in an octagonal shape in plan view, the wiring pattern intersects with the opening edge other than the corner of the opening 43 substantially perpendicularly and is substantially perpendicular to the opening edge. Since the wiring pattern crossing the line can be configured to have a line width exceeding 8 μm, the breakdown voltage of the membrane 33 can be increased.

Second Embodiment
Next explained is the second embodiment of the invention. FIG. 20 is a plan view of the membrane provided in the flow sensor of this embodiment. FIG. 21 is an explanatory diagram of a cavity portion that constitutes the membrane shown in FIG. 20, (a) is a back view of the cavity portion, (b) is a cross-sectional view taken along the line AA of (a), and (c) is a cross-sectional view. It is BB arrow sectional drawing of (a).

  As shown in FIG. 20, a rectangular membrane 33 is formed by an opening 43 having a rectangular shape in plan view. In the sensing unit 32 and the opening 43, an angle formed by the direction in which the heater 81, the side heat resistance 82, the temperature measurement resistor 83, and the midpoint output unit 84 constituting the sensing unit 32 extend and the opening edges 43 h and 43 i is approximately 45. It is arranged to be °.

  The silicon substrate 40 that forms the cavity 41 on the back surface of the membrane 33 is one in which the crystal plane orientation in the thickness direction is formed on the (100) plane. As shown in FIG. 21A, the cavity 41 is formed with four tapered surfaces 41f as inner wall surfaces. Each of the tapered surfaces 41f facing along the <110> crystal axis is a crystal plane orientation (111) plane, and the inclination angle θ3 is 54.7 °.

By arranging the sensing unit 32 and the opening 43 as described above, the temperature measuring resistor 83 near the opening edge in the wiring pattern constituting the sensing unit 32 can be set non-parallel to the opening edge. In addition, the temperature measuring resistor 83 can be further away from the opening edge than that shown in FIG.
Therefore, the breakdown pressure of the membrane 33 can be increased.

Further, as indicated by reference sign Q1, the wiring portion 83a that is electrically connected to the temperature measuring resistor 83 intersects the opening edges 43h and 43i of the opening 43 substantially perpendicularly. Further, as indicated by reference sign Q2, the wiring portion 82a that is electrically connected to the indirectly heated resistor 82 intersects the opening edges 43h and 43i of the opening substantially perpendicularly. Furthermore, the wiring part 81a that is electrically connected to the heater 81 intersects the opening edges 43h and 43i of the opening substantially perpendicularly. In addition, each wiring portion that intersects the opening edge substantially perpendicularly is formed with a line width exceeding 8 μm.
Therefore, the breakdown voltage of the membrane 33 can be further increased.

<Third Embodiment>
Next explained is the third embodiment of the invention. FIG. 22 is a plan view of a membrane provided in the flow sensor of this embodiment. As shown in the figure, the opening 43 may be formed in a circular shape in plan view, and the membrane 33 may be formed in a circular shape in plan view. According to this structure, as indicated by reference numerals Q1 and Q2, the opening edge 43j and the wiring portions 81a, 82a and 83a can be crossed substantially vertically, so that the breakdown voltage of the membrane 33 can be increased.

<Summary>
From the above verifications and experiments, in order to realize a flow sensor including a membrane having a small thickness and a high breakdown voltage, it is desirable to manufacture the membrane in the following structure.

(1) Among the wiring patterns constituting the sensing unit 32, a wiring pattern parallel to the opening edge of the opening 43 is arranged at a position as far away as possible from the opening edge. If possible, it arrange | positions over 50 micrometers inside from an opening edge.
(2) Among the wiring patterns constituting the sensing unit 32, the wiring pattern parallel to the center of the opening edge of the opening 43 is separated as far as possible from the opening edge.

(3) Of the wiring patterns constituting the sensing unit 32, wiring patterns parallel to the opening edge of the opening 43 are reduced as much as possible.
(4) Of the wiring patterns constituting the sensing unit 32, the line width of the wiring pattern that intersects the opening edge of the opening 43 substantially perpendicularly is made as thick as possible. If possible, the line width should be greater than 8 μm.

(5) Of the wiring patterns 86 that intersect the opening edge of the opening 43 substantially perpendicularly, the wiring pattern that passes through the opening edge other than the corner of the opening 43 intersects the opening edge substantially perpendicularly, and the opening 43 The wiring pattern that passes through the corner of the wire intersects with the corner at an acute angle.

<Other embodiments>
The planar shape of the opening 43 (the planar shape of the membrane 33) is not limited to the shape described above, and can be changed as long as the requirements of the present invention are satisfied.

30 ... Flow sensor, 32 ... Sensing part, 33 ... Membrane (bottom),
40 ... Silicon substrate 41 ... Cavity (recess) 43 ... Opening
43a to 43j .. opening edge (bottom edge), 80 .. wiring pattern, 81 .. heater,
82 .. Side heat resistance, 83 .. Resistance temperature detector, 84.

Claims (13)

A recess is formed on the back surface of the substrate, and a semiconductor substrate having a wiring pattern formed on the substrate surface is provided.
In the flow sensor in which the bottom of the recess is formed thin, and the sensing part is formed on the substrate surface of the bottom of the wiring pattern.
Of the wiring pattern formed on the substrate surface of the bottom portion, a portion that intersects the edge of the bottom portion substantially perpendicularly is formed with a width exceeding 8 μm. The planar shape seen from the surface side of the bottom is formed in a rectangle,
2. The flow sensor according to claim 1, wherein an angle formed between an extending direction of a wiring pattern constituting the sensing unit and an edge of the bottom portion is approximately 45 °.   3. The wiring pattern formed on the substrate surface of the bottom portion, wherein a portion passing through an edge other than the corner portion of the bottom portion intersects the edge substantially perpendicularly. The described flow sensor. The planar shape seen from the surface side of the bottom is formed in an octagon,
4. The wiring pattern formed on the substrate surface of the bottom portion, wherein a portion passing through an edge other than the corner portion of the bottom portion intersects the edge substantially perpendicularly. The described flow sensor. The semiconductor substrate is an SOI substrate comprising a silicon support substrate, a silicon oxide film formed on the surface of the support substrate, and a silicon layer formed on the surface of the silicon oxide film,
The recess is formed on the back side of the support substrate;
The bottom is made of the silicon oxide film,
The flow sensor according to claim 1, wherein the wiring pattern is formed from the silicon layer.   The flow rate sensor according to claim 5, wherein a crystal plane orientation in a thickness direction of the support substrate is a (100) plane.   6. The flow sensor according to claim 5, wherein a crystal plane orientation in a thickness direction of the support substrate is a (110) plane.   8. The flow sensor according to claim 5, wherein a crystal plane orientation in a thickness direction of the silicon layer is a (100) plane. 9.   The flow rate sensor according to any one of claims 5 to 8, wherein crystal plane orientations in a thickness direction of the support substrate and the silicon layer are different.   The flow sensor according to claim 5, wherein the silicon layer is made of single crystal silicon.   11. The flow sensor according to claim 5, wherein a thickness of the silicon layer is 0.7 μm or more.   The flow rate according to any one of claims 1 to 11, wherein a step is formed between a portion where the wiring pattern is formed and a portion where the wiring pattern is not formed in the bottom portion. Sensor.   13. The sensing unit according to claim 1, wherein the sensing unit includes a heater and a temperature measuring resistor for measuring the temperature of the heater, and outputs a signal corresponding to a gas flow rate. The flow sensor according to any one of the above.

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