JP4253976B2 - Flow sensor - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a flow sensor that detects a flow rate of a fluid.
[0002]
[Prior art]
Conventionally, various flow sensors have been proposed in which a film-structured heater (heating element) and a temperature measuring element are provided on a semiconductor substrate and the flow rate of the fluid flowing through the heater and the temperature measuring element is measured (Japanese Patent Publication No. 6-6). 43906, JP-A-7-174600, JP-A-9-243423, etc.).
[0003]
FIG. 20 shows an example of a conventional flow sensor. A hollow portion 6 is formed in the substrate 1, and a bridge 2 having a thin film structure is provided on the hollow portion 6 so as to bridge the hollow portion 6. In the bridge 2, the heater 3 is formed in the center, and an upstream temperature measuring body 51 and a downstream temperature measuring body 52 are formed on both sides thereof. A fluid thermometer 4 for detecting the temperature of the fluid is formed on the upstream side of the fluid flow indicated by the white arrow in the figure on the substrate 1 other than the bridge 2.
[0004]
In such a flow sensor, the heater 3 is heated and driven so as to reach a temperature higher than the fluid temperature obtained from the fluid thermometer 4. As the fluid flows, the upstream temperature sensing element 51 is deprived of heat and the temperature is lowered, and the downstream temperature sensing element 52 is heated by the heat from the heater 3 and the temperature rises. The fluid flow velocity is measured (detected) from the temperature difference of the side temperature measuring element 52.
[0005]
[Problems to be solved by the invention]
In the flow sensor having the above-described structure, the temperature difference between the upstream temperature measuring body 51 and the downstream temperature measuring body 52 is as shown in FIG. As can be seen from FIG. 21, the linearity is good in the low flow rate region, but the linearity is deteriorated in the high flow rate region. This is because the upstream side temperature sensing element 51 is cooled to about the fluid temperature when the flow rate is increased, and the temperature change is less with respect to the flow rate, and the downstream side temperature sensing element 52 is cooled by the flow rather than the heating from the heater 3 by the flow. This is because the difference in temperature does not occur as a result. For this reason, the measurement is limited on the high flow rate side.
[0006]
The present invention has been made in view of the above problems, and an object thereof is to increase the measurement limit on the high flow rate side.
[0007]
[Means for Solving the Problems]
  In order to achieve the above object, the invention described in claim 1 includes a heating element and a temperature measuring element, and detects the flow rate of the fluid based on the measured value of the temperature measuring element when the heating element generates heat.,It was configured to change the temperature distribution of the heating element according to the flow rate of the fluidA flow sensor, wherein in a high flow rate region where the flow rate is greater than a predetermined threshold value, a heat generation amount in a portion close to the temperature sensing element in the heating element is larger than in a low flow rate region, and at least in a high flow rate region. In the above, the amount of heat generated by the heating element was increased step by step as the temperature measuring element was approached.It is characterized by that.
[0008]
  In the conventional one, the temperature distribution of the heating element was constant regardless of the flow rate, so the measurement limit was likely to occur on the high flow rate side, but the temperature distribution of the heating element was changed according to the flow rate as in this invention, If the temperature distribution to the temperature measuring element is increased when the flow rate becomes high, the measurement limit on the high flow rate side can be increased.In addition, at least in the high flow rate region, the heat generation amount of the heating element is increased stepwise as it approaches the temperature measuring body, so that the measurement limit of the flow rate can be increased while reducing waste of power consumption.
[0009]
The heating element and the temperature measuring element are arranged on the upstream side of the heating element, or the temperature measuring element is arranged on the downstream side of the heating element, or the temperature measuring element It can take the form of being arranged on both sides of the heating element. Further, the heating element and the temperature measuring element are preferably formed in a thin-film bridge or diaphragm provided on a substrate having a cavity.
[0013]
  Claims2As in the invention described in, the heating element of the heating element according to the flow rate of the fluid,InsideTemperature distributionIs not uniformBy doing so, it is possible to increase the linearity of the temperature of the temperature measuring element.
[0014]
  Claims3The intermediate terminal of the heating element as in the invention described inControl voltage applied to at least three or more terminalsBy doing so, it is possible to change the temperature distribution of the heating element while reducing the power consumption as compared with the case where the heating value of the entire heating element is increased.
[0015]
  The temperature measuring element and heating element described above are claimed in the claims.4As in the invention described in 1, the wiring pattern of one continuous resistorDifferent parts insideCan be formed. In this case, the claim5If a plurality of terminals are connected to the wiring pattern of the resistor and the plurality of terminals are selected, the resistor is used as a heating element and a temperature measuring element. The parts can be used properly after production.
[0016]
  Claims6As in the invention described in (1), if a part of the wiring pattern of the resistor is set as an unused area, power consumption can be reduced.
[0017]
  Claims7As described in the invention described above, the heating element can be formed by one continuous resistor wiring pattern, and a part thereof can be used as an unused area. Also in this case, the power consumption can be reduced by setting a part of the wiring pattern of the resistor as an unused area. Claims8If a plurality of terminals are connected to the wiring pattern of the resistor and the plurality of terminals are selected, the resistor is used as a part for use as a heating element and as an unused area. It can be properly used for the part to be used after manufacturing.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
FIG. 1 is a perspective view of a thermal flow sensor according to the first embodiment of the present invention, and FIG. 2 is a cross-sectional view taken along line AA of FIG.
[0024]
As shown in FIGS. 1 and 2, a cavity 1 is formed in a substrate 1 (for example, a semiconductor substrate using Si), and a bridge 2 is provided with an electrically insulating film so as to bridge the cavity 6. ing. In the bridge 2, a heater 3 that forms a heating element is formed at the center, and a temperature measuring body 5 is formed on one side of the heater 3. The heater 3 and the temperature measuring body 5 are formed of a metal film such as Pt. Further, a fluid thermometer 4 for detecting the temperature of the fluid is formed on the upstream side of the flow of the fluid (for example, air) indicated by the white arrow in the drawing on the substrate 1. Note that TR 1, TR 2, T 1, T 2, H 1, Hm 1, and H 2 in the figure indicate electrode terminals of the fluid thermometer 4, the temperature measuring body 5, and the heater 3, respectively.
[0025]
The flow sensor according to the first embodiment has one temperature measuring element 5 and one heater 3, and the temperature measuring element 5 is disposed upstream of the heater 3 (hereinafter, upstream two-wire flow). Sensor).
[0026]
The fluid thermometer 4 described above is formed of metal wiring, and the temperature is measured from the resistance value fluctuation. Based on the fluid temperature measured by the fluid thermometer 4, the heater 3 is controlled to be heated so as to be higher than the fluid temperature by ΔT. Specifically, the voltage applied to both terminals H1 and H2 of the heater 3 is controlled by a control circuit (not shown). Usually, the heater 3 is heated by the Joule heat of the current flowing through the heater 3 by applying a voltage to the both terminals H1 and H2. The value of ΔT described above is a temperature of about 200 ° C., for example.
[0027]
Then, under such heating control of the heater 3, in a processing circuit (not shown), the temperature measured by the upstream temperature sensing element 5 (the measured value of the upstream temperature sensing element 5, that is, the resistance value of the upstream temperature sensing element 5 is obtained. The flow rate of the fluid is measured (detected) based on the difference between the measured temperature and the temperature measured by the fluid thermometer 4.
[0028]
Here, when there is no wind, as shown in FIG.₀When the flow rate is low, the temperature T is measured by the upstream temperature sensing element 5 as shown in FIG._LWhen the flow rate is high, the temperature T is measured by the upstream temperature measuring element 5 as shown in FIG._HIs measured. However, the temperature T measured at high flow rates_HIs the temperature T measured at low flow rates_LBecause it is lower, its measurement is limited. The measurement limit of the flow rate of such a flow sensor is determined by the fact that the upstream temperature sensing element 5 is cooled to about the fluid temperature and the temperature does not change with respect to the flow velocity.
[0029]
Therefore, in this embodiment, the heater 3 is provided with the intermediate terminal Hm1, and the voltage applied to the intermediate terminal Hm1 is controlled to increase the measurement limit of the flow rate.
[0030]
That is, in a region where the flow rate is lower than a certain threshold value (hereinafter referred to as a low flow rate region), the intermediate terminal Hm1 is set to a voltage such that the current of the entire floating or heater 3 is uniform, for example, as in a normal case. A uniform current flows through the entire heater 3. In this case, whether or not the flow rate is lower than a certain threshold value can be determined by whether or not the temperature measured by the temperature measuring body 5 is higher than a certain threshold value, for example.
[0031]
Further, in a high region where the flow rate is equal to or higher than a certain threshold (hereinafter referred to as a high flow region), a predetermined voltage is applied to the intermediate terminal Hm1, thereby changing the temperature distribution of the heater 3 so increase. Here, the flow rate measurement limit occurs when the temperature of the temperature sensing element 5 is cooled to near the fluid temperature, so the temperature of the upstream portion of the heater 3 is increased (that is, the measurement temperature at the time of high flow rate is shown in FIG. T) as shown in_HBy increasing it to ', the measurement limit of the flow rate can be increased.
[0032]
In this case, on the processing circuit side that performs flow rate detection, in consideration of the voltage application state to the intermediate terminal Hm1, the flow rate can be accurately detected in both cases of low flow rate and high flow rate. In the embodiment described below, when a voltage is applied to the intermediate terminal to increase the measurement limit on the high flow rate side, the flow rate detection is performed in consideration thereof.
[0033]
In the embodiment described above, the heater 3 is provided with the intermediate terminal Hm1 to increase the flow rate measurement limit. However, when the flow rate exceeds a certain threshold, the voltage applied to both ends H1 and H2 of the heater 3 is increased. Then, the current flowing through the entire heater 3 may be increased to raise the temperature of the entire heater 3. Even if it does in this way, since it can prevent that the upstream temperature sensing element 5 is cooled, the measurement limit of flow volume can be raised. However, if this method is compared with the method using the intermediate terminal Hm1, the method using the intermediate terminal Hm1 is preferable because the method using the intermediate terminal Hm1 consumes less power.
[0034]
In the above-described embodiment, the current flowing through the entire heater 3 is made constant and the temperature distribution of the heater 3 is made almost uniform in the low flow rate region. However, the temperature distribution of the heater 3 is changed. Also good. For example, the ratio of the voltage between the upstream terminal H1 and the intermediate terminal Hm1 and the voltage between the downstream terminal H2 and the intermediate terminal Hm1 is set so that the upstream temperature is lower than the downstream temperature even at a low flow rate. May be set to be higher. In this case, in the high flow rate region, the voltage between the upstream terminal H1 and the intermediate terminal Hm1, the downstream terminal H2 and the intermediate terminal are set so that the difference between the upstream temperature and the downstream temperature is further increased. The ratio of the voltage to Hm1 is changed. Specifically, the voltage between the upstream terminal H1 and the intermediate terminal Hm1 is made larger than the voltage between the downstream terminal H2 and the intermediate terminal Hm1.
[0035]
In the embodiment described above, one intermediate terminal Hm1 is provided. However, a plurality of intermediate terminals may be provided so that the temperature distribution at a high flow rate can be finely controlled. FIG. 4 shows an example in which a plurality of intermediate terminals Hm1, Hm2, and Hm3 are provided. In this case, the amount of heat generated between the voltage terminals gradually decreases from the upstream side to the downstream side at a high flow rate, in other words, the amount of heat generated by the heater 3 is controlled to increase stepwise toward the temperature measuring body 5. Thus, the measurement limit of the flow rate can be increased while reducing waste of power consumption. The same control may be performed not only at a high flow rate but also at a low flow rate.
[0036]
In the above-described control, the voltage applied to the intermediate terminal may be finely controlled so that the linearity of the temperature of the temperature measuring element 5 with respect to the flow rate becomes the best. Here, raising the linearity of the temperature of the temperature sensing element 5 has the following merit. Generally, a flow sensor is required to detect fluid pulsation. Pulsation means that the flow rate of fluid changes periodically. The merit of linearity will be described with reference to FIG. 5 showing the behavior of the flow sensor when pulsation exists.
[0037]
Since an actual flow sensor always has a response delay, the signal is always less than the change in flow rate due to actual pulsation (the detected amplitude is smaller than the amplitude of the pulsation). At this time, it is important to correctly detect the average flow rate of pulsation. This is because if the average flow rate of pulsation can be detected correctly, the total flow rate of the flowing fluid can be detected correctly. FIG. 5A shows characteristics when the temperature is proportional to the flow rate. In this case, the actual average flow rate matches the apparent average flow rate (average flow rate detected by the sensor). FIG. 5B shows characteristics when the temperature is not proportional to the flow rate. In this case, the apparent average flow rate is lower than the actual average flow rate. The apparent average flow rate is lower than the actual average flow rate because the temperature-flow rate curve is convex upward. Conversely, when the temperature-flow rate curve is convex downward, the apparent average flow rate exceeds the actual average flow rate. Therefore, a linear flow sensor in which the temperature is proportional to the flow rate is preferable.
[0038]
It should be noted that the temperature distribution on the heater 3 is not strictly constant when the flow rate is 0, and is highest near the center and lowest at the end. However, the temperature distribution can be made uniform by using the multi-terminal resistor structure described above. That is, the temperature distribution can be made uniform by setting the voltage slightly higher at only the end portions of many resistors and setting the heat generation amount at the end portions to be larger than the heat generation amount at the central portion.
[0039]
Note that the flow sensor is not limited to a bridge structure, and has a diaphragm structure having a diaphragm 20 as shown in FIGS. 6 and 7 (cross-sectional view taken along line BB in FIG. 6). May be. In the following embodiments, a flow sensor having a bridge structure will be described, but it is possible to change it to a diaphragm structure.
(Second Embodiment)
In the above-described first embodiment, the temperature measuring body 5 is provided on the upstream side of the heater 3. However, as shown in FIG. 8, the temperature measuring body 5 is provided on the downstream side of the heater 3 and one temperature measurement is performed. It is good also as what has the body 5 and the one heater 3, and the temperature measuring body 5 is arrange | positioned downstream from the heater 3 (henceforth a downstream 2 wire type flow sensor).
[0040]
When the temperature measuring body 5 is arranged downstream of the heater 3 as in this embodiment, the cooling effect of the temperature measuring body 5 by the flow is greater than the effect of the heat of the heater 3 heating the temperature measuring body 5 by the flow. As this becomes larger, the measurement limit of the flow rate on the high flow rate side is determined. Therefore, in this embodiment, the following control is performed.
(1) In the low flow rate region, as in the first embodiment, the intermediate terminal Hm1 is set to a voltage, for example, that is floating or the current of the entire heater 3 becomes uniform, and a uniform current flows through the entire heater 3. .
(2) In the high flow rate region, a voltage is applied to the intermediate terminal Hm1 to raise the temperature of the downstream portion of the heater 3. As a result, heating in the vicinity of the temperature sensing element 5 can be increased, and the measurement limit can be increased.
(Third embodiment)
In the first and second embodiments described above, the temperature measuring body 5 is positioned upstream and downstream of the heater 3, but the temperature measuring body 5 can be arranged at other positions. For example, as shown in FIG. 9, the temperature measuring body 5 may be disposed directly beside the heater 3. The control method in this case is the same as in the first embodiment.
(Fourth embodiment)
In the first to third embodiments, the two-wire flow sensor having one temperature measuring body 5 and one heater 3 is shown. However, the temperature sensor has two temperature measuring bodies and one heater, and two temperature measuring elements are provided. The body may be disposed upstream and downstream of the heater (hereinafter referred to as a three-wire flow sensor).
[0041]
FIG. 10 is a perspective view of a three-wire flow sensor according to this embodiment.
[0042]
On the basis of the fluid temperature measured by the fluid thermometer 4, the heater 3 is controlled to be heated so as to be higher than the fluid temperature by ΔT. Under such heating control of the heater 3, the flow rate of the fluid is determined based on the difference between the temperature measured by the upstream temperature measuring body 51 and the temperature measured by the downstream temperature measuring body 52 in a processing circuit (not shown). Measured.
[0043]
In the case of the three-wire flow sensor according to this embodiment, the flow rate measurement limit is that the temperature of the upstream temperature measuring body 51 is cooled to near the fluid temperature, and the cooling of the downstream temperature measuring body 52 by the flow is downstream by the heater 3. It is determined by exceeding the heating of the temperature measuring body 52. Therefore, in this embodiment, the following control is performed.
(1) In the low flow rate region, the intermediate terminals Hm1, Hm2, and Hm3 are floated, for example, so that a uniform current flows through the heater 3 as in the normal case.
(2) In the high flow rate region, by applying a predetermined voltage to the upstream intermediate terminal Hm1 and the downstream intermediate terminal Hm3, the temperature distribution of the heater 3 is changed, and the temperatures of the upstream and downstream portions of the heater 3 are increased. As described above, the flow rate measurement limit is that the temperature of the upstream temperature measuring body 51 is cooled to near the fluid temperature, and the cooling of the downstream temperature measuring body 52 by the flow causes the heating of the downstream temperature measuring body 52 by the heater 3. Therefore, the measurement limit of the flow rate can be increased by increasing the temperatures of the upstream and downstream portions of the heater 3.
[0044]
In the above-described embodiment, the temperature measuring bodies 51 and 52 are positioned upstream and downstream. However, if the two temperature measuring bodies 51 and 52 are not completely in a state of being directly next to the flow, the temperature measuring body 51 , 52 can be arranged at positions other than those shown in FIG.
(Fifth embodiment)
In this embodiment, as shown in FIG. 11, when the heater 3 is provided with a large number of terminals H1 to H13 and the maximum usable voltage is Vmax [V], the terminals H1, H3, H5, H7, H9, H11 , H13 is applied with a potential of Vmax [V], and a potential of 0 V is applied to the terminals H2, H4, H6, H8, H10, and H12.
[0045]
When the total resistance value of the heater 3 is R [Ω], when a voltage of Vmax [V] is applied to both ends of the heater 3 (H1 and H12 shown in FIG. 11) as in the prior art, the flowing current is Vmax. / R [A], calorific value is Vmax²/ R [W]. However, when a large number of intermediate terminals are provided and the resistor is divided into n equal parts (12 equal parts in FIG. 11) as shown in FIG. 11, the flowing current is n × Vmax / R [A], and the heat generation amount. Is n²× Vmax²/ R [W], and the current value and the calorific value are simply n times that when voltage is applied to both ends H1 and H12, n²Doubled.
[0046]
Accordingly, when a sufficient current can be obtained and the maximum voltage is limited, the temperature of the heater 3 can be increased by providing a large number of terminals as in this embodiment, and a high flow rate can be obtained. The measurement limit on the side can be increased.
(Sixth embodiment)
As in the fifth embodiment described above, a resistor formed by one continuous wiring pattern and having a large number of terminals H1 to H13 can be regarded as a plurality of resistors. Therefore, any one of the plurality of resistors can be used as a heater, and any other resistor can be used as a temperature measuring body. Therefore, in this embodiment, as shown in FIG. 12, some resistors on the upstream side are used as the temperature measuring element 5, and some resistors on the downstream side are used as the heater 3. The unused area 7 in the figure may or may not be present.
[0047]
In this case, the terminal H1 is used as the measuring terminal of the temperature measuring element 5, and in the low flow rate region, the terminal H3 is set to 0V, the terminal H11 is set to Vmax, and the other terminals are floated to detect the flow rate. If, for example, a voltage of 2/3 Vmax is applied to the terminal H7 with respect to the state of the region, it is possible to perform flow rate detection with an increased flow rate measurement limit, as in the first embodiment.
[0048]
Similarly, as shown in FIG. 13, the downstream side can be used as the temperature measuring body 5 and the upstream side can be used as the heater 3. In this case, the terminal H13 is used as a measurement terminal of the temperature sensing element 5, the terminal H3 is set to Vmax, the terminal H11 is set to 0V in the low flow rate range, and the other terminals are floated to detect the flow rate. In the high flow rate range, the low flow rate is set. For example, if a voltage of 2/3 Vmax is applied to the terminal H7 in the region state, the flow rate detection with the flow rate measurement limit raised can be performed as in the second embodiment.
[0049]
Similarly, the downstream and upstream sides can be temperature measuring elements, and the middle part can be a heater. If it does in this way, it will become a controllable flow sensor similarly to 4th Embodiment.
[0050]
The control methods in these cases are the same as those in the first to fourth embodiments, respectively. However, in this embodiment, there is a merit that the length and the positional relationship between the temperature measuring body 5 and the heater 3 can be changed after manufacturing. .
[0051]
For example, in a two-wire flow sensor having an upstream temperature sensor 5, when it is desired to measure only a low-speed and low-flow rate, it is known that the width of the heater 3 may be narrow, so as shown in FIG. Resistors are distributed from the upstream side such as the temperature measuring element 5, the heater 3, and then the unused area 7. In this case, since the resistor far from the temperature sensing element 5 is not used as the heater 3 in the unused area 7, waste of power consumption can be saved. On the other hand, when it is desired to measure including a high flow rate, the unused region 7 is reduced or eliminated, the width of the heater 3 is increased as much as possible, or the same control as in the first embodiment is performed. The measurement limit can be increased.
[0052]
Moreover, the unused area | region 7 can also be utilized for judging deterioration (for example, self-diagnosis) of the heater 3. FIG. That is, if the terminals H1 to H13 are arranged at the same interval and the resistors have the same width, the resistors should have the same resistance value. Accordingly, if the unused area 7 does not deteriorate, it can be determined whether the heater 3 has deteriorated by obtaining the difference between the resistance values of the unused area 7 and the heater 3. Moreover, even if it does not arrange | position each terminal H1-H13 at the same space | interval, or makes a resistor the same width, if the resistance value of the unused area | region 7 and the heater 3 is compared by the arithmetic processing by the processing circuit side, Deterioration of the heater 3 can be detected. Even if the unused area 7 is not used, it is also possible to detect the deterioration of the heater 3 by comparing the resistance values of the heater 3 and the temperature measuring element 5.
[0053]
In the above-described embodiment, the temperature measuring body 5 may be formed by another resistance wire. For example, the embodiment shown in FIG. 12 may be configured as shown in FIG. In this case, although it becomes the structure similar to 1st Embodiment, it becomes possible to set the unused area | region 7 after manufacture, and it can be used as a flow sensor without wasteful power consumption according to a use purpose.
(Seventh embodiment)
In this embodiment, as shown in FIG. 15, the resistor is composed of a large number of terminals H <b> 1 to H <b> 21, and the first heater 31, the temperature sensor 5, the second heater 32, and the unused area 7 are arranged from the upstream side. It has become. This flow sensor works in the same way as the upstream two-wire flow sensor.
[0054]
The feature of this embodiment resides in that the heater 31 exists further upstream of the temperature sensing element 5. As a result, it is possible to prevent the temperature of the temperature sensing element 5 from dropping to the same level as the fluid temperature in the high flow rate range, and to increase the measurement limit on the high flow rate side.
[0055]
Furthermore, when increasing the measurement limit on the high flow rate side, the same control as in the first embodiment may be performed. For example, the terminal H4 is used as a measurement terminal of the temperature sensing element 5, in the low flow rate range, the terminals H1 and H15 are set to 0V, the terminals H3 and H5 are set to Vmax, and the other terminals are floated to detect the flow rate. If, for example, a voltage of 1/2 Vmax is applied to the terminal H9 in the low flow rate state, the flow rate detection with the flow rate measurement limit raised can be performed as in the first embodiment.
[0056]
This embodiment is applicable not only to the upstream two-wire flow sensor but also to the downstream two-wire heater as shown in FIG. In this case, the terminal H18 is used as the measurement terminal of the temperature measuring element 5, and in the low flow rate range, the terminals H17 and H19 are set to Vmax, the terminals H7 and H21 are set to 0V, and the other terminals are floated to detect the flow rate. If, for example, a voltage of 1/2 Vmax is applied to the terminal H13 in the low flow rate state, the flow rate detection with the flow rate measurement limit raised can be performed as in the second embodiment.
[0057]
Note that the heaters 31 and 32 do not necessarily have to be wider in the heater 32 (or 31), and the width can be arbitrarily set.
(Eighth embodiment)
In the seventh embodiment described above, what is applied to the two-wire heater is shown, but the present invention can be similarly applied to a three-wire heater. A planar configuration of the flow sensor in this case is shown in FIG.
[0058]
As shown in the figure, the flow sensor according to this embodiment is composed of a resistor having a large number of terminals H1 to H21, and from the upstream side, the first heater 31, the upstream temperature measuring body 51, the second heater 32, The downstream temperature measuring body 52, the third heater 33, and the unused area 7 are formed. This flow sensor works in the same way as a three-wire flow sensor.
[0059]
The feature of this embodiment is that, in addition to the heater 32, the heater 31 exists upstream of the upstream temperature measuring body 51 and the heater 33 exists downstream of the downstream temperature measuring body 52. As a result, in the high flow rate region, it is possible to prevent the temperature of the upstream temperature measuring body 51 and the downstream temperature measuring body 52 from dropping to the same level as the fluid temperature to some extent, and the measurement limit on the high flow rate side is reduced. It is possible to increase.
[0060]
Furthermore, when increasing the measurement limit on the high flow rate side, the same control as in the fourth embodiment may be performed. For example, the terminals H4 and H16 are used as measuring terminals of the temperature sensing element 5, and in the low flow rate range, the terminals H1, H15, and H17 are set to 0V, the terminals H3, H5, and H19 are set to Vmax, and the other terminals are floated to detect the flow rate. In the high flow rate region, for example, if a voltage of 2/3 Vmax is applied to the terminal H7 and a voltage of 1/2 Vmax is applied to the terminal H13 with respect to the state of the low flow rate region, as in the fourth embodiment, Flow rate detection can be performed with an increase in the flow rate measurement limit.
[0061]
In addition, the width of the heaters 31, 32, and 33 is not necessarily the widest width of the heater 32, and the width can be arbitrarily set.
(Flow sensor manufacturing method)
The flow sensor described above can be manufactured by a manufacturing method described below. Each embodiment described above represents the first embodiment because only the wiring patterns of the heater 3 (31, 32, 33), the fluid thermometer 4, and the temperature measuring element 5 (51, 52) are different. The manufacturing method will be described. FIG. 18 shows the manufacturing process.
[Step of FIG. 18A]
First, a single crystal silicon substrate is used as the semiconductor substrate 1, and a lower film 11 is formed thereon. This lower film 11 is made of Si._ThreeN_FourFilm and SiO₂A two-layer insulating film is formed by combining the films, and the stress generated in the lower film 11 is relieved by the combination of the compressive stress film and the tensile stress film. Thereafter, as a film constituting the heater 3, the fluid temperature film 4, and the temperature measuring body 5, a Pt film is deposited at 2000 ° C. by a vacuum vapor deposition machine. At that time, a Ti layer is deposited as an adhesive layer between the Pt film and the lower film 11 in a thickness of 50 mm. And it patterns to the shape of the heater 3, the fluid thermometer 4, and the temperature measuring body 5 by an etching. By this patterning, the terminals of the heater 3, the fluid thermometer 4, and the temperature measuring body 5 (illustrated as the electrode extraction portion 12 in the figure) are formed at the same time.
[Step of FIG. 18B]
Similar to the lower film 11, Si_ThreeN_FourFilm and SiO₂A two-layer upper film 13 made of a film is formed. Here, the heater 3 is arranged substantially at the center of the film structure, and the film configurations of the upper film 13 and the lower film 11 are arranged symmetrically with respect to the heater 3, so that the warp fluctuation does not occur even if the temperature changes. A structure strong against heat stress can be formed. And the area | region which forms the cavity part 6, and the electrode extraction part 12 of the heater 3, the fluid thermometer 4, and the thermometer 5 are opened by an etching.
[Step of FIG. 18C]
After depositing 5000 Ａｕ of Au on the entire surface, etching is performed to form an etching protective film 14 so as to cover the electrode lead-out portion 12. This etching protective film 14 is used to protect the electrode lead-out portion 12 against the Si etching solution used in the next process and to enhance the adhesion with Au wiring when external wiring is used.
[Step of FIG. 18D]
Cavity 6 is formed by anisotropic etching of silicon from the surface side with a TMAH solution.
[0062]
As described above, the flow sensor shown in FIGS. 1 and 2 can be manufactured.
[0063]
When the flow sensor has a diaphragm structure as shown in FIGS. 6 and 7, it can be manufactured by the following manufacturing method. FIG. 19 shows the manufacturing process.
[Step of FIG. 19A]
Similarly to the process of FIG. 18A, the lower film 11 is formed on the silicon substrate 1, and the heater 3, the fluid temperature film 4, and the temperature measuring element 5 are formed thereon by patterning.
[Step of FIG. 19B]
Similar to the lower film 11, Si_ThreeN_FourFilm and SiO₂A two-layer upper film 13 made of a film is formed, and the heater 3, the fluid thermometer 4, and the electrode lead-out portion 12 of the temperature measuring body 5 are opened by etching. Further, a predetermined position of the film formed on the back surface of the silicon substrate 1 is removed by etching.
[Step of FIG. 19C]
The cavity 6 is formed by anisotropically etching the back side of the silicon substrate 1 until the lower film 11 is exposed.
[0064]
In this way, the flow sensor shown in FIGS. 6 and 7 can be manufactured.
[0065]
In the manufacturing method shown in FIGS. 18 and 19, polysilicon, NiCr, TaN, SiC, W, or the like is used in addition to the Pt film as the film for forming the heater 3, the fluid thermometer 4, and the temperature measuring element 5. be able to. In addition, as the lower film 11 and the upper film 13, any film that can protect the heater 3 or the like can be used.₂, Al₂O_Three, Ta₂O_FiveA single film or a multilayer film such as an MgO film can be used. Further, the etching protective film 14 is not necessarily required if the exposed electrode lead-out portion 12 is resistant to the etching solution, and other materials can be used as long as they are resistant to etching and can be bonded to the connection wiring. It may be. In addition, the etching for forming the cavity 6 may be other than anisotropic etching using a TMAH solution as long as the cavity 6 can be formed.
[0066]
In the various embodiments described above, the flow sensor can be applied to the detection of the flow rate of various fluids in addition to the detection of the flow rate of a gas such as air. Further, although the wirings such as the heater 3 and the temperature sensing element 5 are shown on the bridge 2 or the diaphragm 20, they are not directly provided on the substrate 1 even if the bridge structure or the diaphragm structure is not necessarily used. May be arranged.
[Brief description of the drawings]
FIG. 1 is a perspective view of a thermal flow sensor according to a first embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along line AA in FIG.
FIG. 3 is a diagram showing temperatures measured at no flow, low flow, and high flow.
FIG. 4 is a diagram showing an embodiment in which a plurality of intermediate terminals are provided in the embodiment shown in FIG. 1;
FIG. 5 is a diagram showing the behavior of the flow sensor when pulsation exists.
6 is a perspective view of a thermal flow sensor having a diaphragm structure having the bridge structure shown in FIG. 1. FIG.
7 is a cross-sectional view taken along line BB in FIG.
FIG. 8 is a plan view of a thermal flow sensor according to a second embodiment of the present invention.
FIG. 9 is a plan view of a thermal flow sensor according to a third embodiment of the present invention.
FIG. 10 is a perspective view of a thermal flow sensor according to a fourth embodiment of the present invention.
FIG. 11 is a diagram showing a planar configuration of a bridge portion of a thermal flow sensor according to a fifth embodiment of the present invention.
FIG. 12 is a diagram showing a planar configuration of a bridge portion of a thermosensitive flow sensor according to a sixth embodiment of the present invention in which an upstream side is a temperature measuring body and a downstream side is used as a heater.
FIG. 13 is a diagram showing a planar configuration of a bridge portion of a thermal flow sensor according to a sixth embodiment of the present invention, in which the downstream side is a temperature measuring element and the upstream side is used as a heater.
14 is a diagram showing an example in which a temperature measuring element is formed by another resistance wire with respect to the embodiment shown in FIG.
FIG. 15 is a diagram showing a planar configuration of a bridge portion of a thermal flow sensor according to a seventh embodiment of the present invention, which is applied to an upstream two-wire flow sensor.
FIG. 16 is a diagram showing a planar configuration of a bridge portion of a thermal flow sensor according to a seventh embodiment of the present invention, which is applied to a downstream two-wire flow sensor.
FIG. 17 is a diagram showing a planar configuration of a bridge portion of a thermal flow sensor according to an eighth embodiment of the present invention.
FIG. 18 is a process diagram showing a method of manufacturing a flow sensor having a bridge structure.
FIG. 19 is a process diagram showing a manufacturing method of a flow sensor having a diaphragm structure.
FIG. 20 is a perspective view of a conventional thermal flow sensor.
FIG. 21 is a diagram showing a characteristic of a temperature difference between the upstream side temperature sensor and the downstream side temperature sensor in the conventional flow sensor shown in FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Board | substrate, 2 ... Bridge, 3, 31, 32 ... Heater, 4 ... Fluid thermometer,
5, 51, 52 ... temperature measuring element, 6 ... cavity, 7 ... unused area.

Claims (8)

Having a heating element and temperature sensing element, to detect the flow rate of the fluid based on the measured value of the temperature sensing element at the time of heat generation of the heating element, the temperature distribution of the heating element in accordance with the flow rate of the fluid A flow sensor configured to change ,
In the high flow rate region where the flow rate is greater than a predetermined threshold, the calorific value of the portion close to the temperature sensing element in the heating element is increased compared to the low flow rate region, and at least in the high flow rate region, A flow sensor characterized in that the amount of heat generated by a heating element increases stepwise as it approaches the temperature measuring element . 2. The flow according to claim 1 , wherein the temperature distribution inside the heating element is not uniform according to the flow rate of the fluid so that the measurement value of the temperature measuring element is proportional to the flow rate. Sensor. The heating element has an intermediate terminal in addition to both terminals to which a voltage is applied, and is configured to change the temperature distribution of the heating element by controlling the voltage applied to at least three or more terminals . The flow sensor according to claim 1 or 2 , wherein The flow sensor according to any one of claims 1 to 3 , wherein the temperature measuring element and the heating element are formed at different portions in a wiring pattern of one continuous resistor. A plurality of terminals are connected to the wiring pattern of the resistor, and the plurality of terminals are selectively used for the heating element and the temperature measuring element, and the heating element and the temperature measuring instrument are used. The flow sensor according to claim 4 , wherein a body is formed at different portions in the wiring pattern . Flow sensor according to claim 4 or 5 part of the wiring pattern of the resistor, characterized in that has a unused area passes no current. 2. The heating element is formed by a wiring pattern of one continuous resistor, and a part of the wiring pattern of the resistor is an unused area where no current flows. Or the flow sensor of 2 . Wherein the wiring pattern of the resistor, a plurality of terminals are connected, according to claim 7, wherein the plurality of terminals, characterized in that it selectively used for the the heating element and for the unused area The flow sensor described in 1.

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