JP3969564B2 - Flow sensor - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a flow sensor used for measuring the flow velocity or flow rate of a fluid flowing in a flow path, and more particularly to a thermal flow sensor.
[0002]
[Prior art]
Various types of thermal flow sensors for measuring the flow velocity and flow rate of fluids have been proposed (eg, Japanese Patent Laid-Open No. 4-295724, Japanese Patent Publication No. 6-25684, Japanese Patent Laid-Open No. 8-146026, etc.) ). In this type of flow sensor, an element equipped with a means for detecting a normal flow velocity is generally installed in a pipe so as to be parallel to the flow of the fluid to be measured, and the spatial flow of the fluid due to the heat generated from the heating element (heater). The temperature distribution is biased by the flow, and this is detected by the temperature sensor (indirect heating type), or the change in power and resistance due to the heat being taken away by the fluid is detected (self-heating type) By doing so, the flow velocity or flow rate is measured.
[0003]
By the way, the conventional flow sensor has been mainly used for non-corrosive gas, but recently, a sensor that can be used for liquid or corrosive gas has been developed. For example, as an example, a flow sensor disclosed in the above-mentioned Japanese Patent Application Laid-Open No. 4-295724 is known.
[0004]
This flow sensor is provided with first and second regions on the first surface of the silicon substrate, a heating element and a temperature sensor are provided in the first region, an ambient temperature sensor is provided in the second region, and the first, In order to thermally isolate and isolate the second region, a third region made of oxidized porous silicon (insulating layer) is provided between the two regions, and the second surface of the silicon substrate receives the fluid flow. It is said. A silicon cap is fixed to the first surface to increase the rigidity of the silicon substrate and protect the heating element, temperature sensor, and ambient temperature sensor.
[0005]
[Problems to be solved by the invention]
However, since the conventional flow sensor described above has a structure in which the silicon substrate is directly exposed to the fluid to be measured, there has been a problem that it cannot be used for corrosive gases and liquids used in semiconductor manufacturing apparatuses and the like.
As a measure for preventing heat conduction from the heating element to the ambient temperature sensor, the first region and the second region are thermally insulated from each other by a third region made of oxidized porous silicon. The substrate itself is made of silicon and has high thermal conductivity, and the heat of the heating element passes through the underside of the insulating layer and is transmitted to the ambient temperature sensor, thus sufficiently preventing the thermal effect of the heating element on the ambient temperature sensor. As a result, the temperature of the ambient temperature sensor rises, and the temperature of the fluid cannot be measured accurately, resulting in a problem that the measurement accuracy is low. Further, since the step of oxidizing the third region by placing the silicon substrate in the oxidation furnace is necessary, the production of the silicon substrate is also troublesome.
[0006]
The present invention has been made to solve the above-described conventional problems. The object of the present invention is to detect the temperature of the fluid with high accuracy without the heat of the heating element being transferred to the ambient temperature detection means by heat conduction. An object of the present invention is to provide a flow sensor that can improve the flow rate detection accuracy.
[0007]
[Means for Solving the Problems]
To achieve the above object, according to a first aspect of the present invention, there is provided a flow sensor having a flow path through which a fluid flows, wherein the flow path includes a thin plate-like substrate formed of any one of stainless steel and sapphire , Formed by a flow path forming member bonded to the substrate, the flow path forming member forming a recess smaller than the substrate on a surface bonded to the substrate, and a space formed between the recess and the substrate is formed with a fluid supply port and fluid outlet communicating with the space, heating elements provided on the surface opposite to the flow path side of said substrate And a heat sink projecting on a surface opposite to the passage of the substrate so as to partition a space between the flow velocity detecting means and the ambient temperature detecting means. The flow rate detection The stage and the ambient temperature detecting means and the heat sink are those provided on the same substrate.
[0008]
In a second aspect of the invention, the flow path forming member is formed of any one of stainless steel, sapphire, and ceramics.
[0011]
In the first invention, when the heating element of the flow rate detecting means is heated, the heat is transferred to the substrate and raises the temperature of the substrate. If there is no heat sink between the heating element and the ambient temperature detection means, the heat transmitted to the substrate is transferred to the ambient temperature detection means by heat conduction, and the temperature of the ambient temperature detection means is increased. If a heat sink is provided between the heating element and the ambient temperature detection means, the heat transmitted to the substrate is transmitted to the heat sink by thermal conduction, and therefore the heat is radiated by the heat sink. Therefore, the temperature of the ambient temperature detecting means hardly changes and the temperature of the fluid is accurately measured. The greater the heat capacity and heat dissipation effect of the heat sink, the less the thermal influence on the ambient temperature detecting means.
Since the flow velocity detection means including the heating element is provided on the surface opposite to the flow path side of the substrate, the fluid does not directly contact the flow velocity detection means, and the corrosive gas or liquid can be selected by selecting the substrate material. Can be used for measurement.
Since the flow rate detecting means is not exposed to the fluid, there is no possibility that dust accumulates, the resistance value changes due to the fluid, or the aging changes, and the stable performance is maintained. Since the substrate is a thin plate-like body, the fluid and the flow velocity detecting means are thermally short-circuited.
[0013]
In the second invention, since the flow path forming member is formed of stainless steel, sapphire or ceramics, it is excellent in corrosion resistance and can be used for measurement of corrosive gas or liquid.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in detail based on embodiments shown in the drawings.
1A, 1B, and 1C are a front view, a cross-sectional view, and a rear view showing an embodiment of a flow sensor according to the present invention, and FIG. 2 is a front view of a sensor unit. In these drawings, a flow sensor generally indicated by reference numeral 1 includes a substrate 4, a plate 5 and a flow path forming member 6 joined to the front and back surfaces 4a and 4b of the substrate 4 by welding, brazing, screws, and the like. The back surface 4b of the substrate 4 and the flow path forming member 6 constitute a part of the flow path 3 of the fluid to be measured (hereinafter referred to as fluid) 2.
[0015]
The substrate 4 is formed in an elongated rectangular thin plate shape, and the outer peripheral edge portion of the back surface 4 b is bonded to the surface of the flow path forming member 6. The material of the substrate 4 is preferably a material having a thermal conductivity lower than that of silicon and having high heat resistance, corrosion resistance, and rigidity. For this reason, in the present embodiment, a thin plate made of stainless steel having a plate thickness of about 50 to 150 μm is formed, and its central portion is a diaphragm-structured sensor portion 4A, which is separated from the plate 5. For this reason, a through hole 7 is formed in the center of the plate 5 corresponding to the sensor portion 4A.
[0016]
In this case, in FIG. 2, the sensor portion 4A having a diaphragm structure is shown as a circle. However, as shown in FIG. The reason is that in the case of a circular shape, if the distance between the ambient temperature sensor 22 and the heat sink 23 is increased in order to improve the thermal balance of the sensor, the diameter of the diaphragm is increased, the length of the heat sink 23 is increased, and the strength of the diaphragm is increased. On the other hand, in the case of an oval shape in the fluid length direction, the diameter of the diaphragm in the short axis direction does not increase even if the distance between the ambient temperature sensor 22 and the heat sink 23 is increased. This is because the length of the diaphragm is not increased, and the strength reduction of the diaphragm can be reduced as compared with the circular shape.
[0017]
In the case where the substrate 4 is made of stainless steel, it is not preferable that the thickness is 50 μm or less because the strength is lowered. Moreover, when it is 150 μm or more, the heat conduction efficiency in the thickness direction of the substrate 4, that is, the heat conduction efficiency between the fluid 2 and the flow velocity detecting means 8 described later, and the heat transfer amount in the direction parallel to the surface of the substrate 4 ( (Heat loss) increases, which is not preferable.
[0018]
An electric insulating film 9 is formed over the entire surface 4 a of the substrate 4. The flow rate detecting means 8 including the plurality of electrode pads 10 and the wiring metal thin film 11 and the ambient temperature detecting means 22 are well-known thin film forming at the center of the surface of the electrical insulating film 9 corresponding to the sensor portion 4A. Formed by technology. For example, a material such as platinum is vapor-deposited on the surface of the electrical insulating film 9 and etched into a predetermined pattern. The flow velocity detection means 8 and the ambient temperature detection means 22 are connected to the electrode pad 10 via the wiring metal thin film 11. Are each electrically connected.
[0019]
The electrical insulating film 9 is made of, for example, a thin silicon oxide (SiO ₂ ) film having a thickness of about several thousand angstroms or a silicon nitride film. For example, sputtering, CVD, or a solvent mixed with silicon oxide is applied to the silicon oxide film and heated to a predetermined temperature to form silicon oxide. The silicon nitride film is formed by sputtering or CVD.
[0020]
The flow velocity detection means 8 includes one heating element (resistance heater) 20 and two temperature sensors 21A and 21B, and constitutes an indirectly heated flow velocity detection means. The heating element 20 is located at the approximate center of the sensor unit 4A. The two temperature sensors 21A and 21B are formed so as to be positioned on the upstream side and the downstream side, respectively, in the flow direction of the fluid 2 with the heating element 20 interposed therebetween. The ambient temperature detection means 22 is used to compensate for the change in ambient temperature, that is, the temperature of the fluid 2, and is further upstream than the upstream temperature sensor 21A near the outer periphery of the sensor unit 4A. It is formed so that it may be located in. The line width of the pattern of the heating element 20 is preferably 10 to 50 μm, and the line width of the patterns of the temperature sensors 21A and 21B and the ambient temperature detecting means 22 is preferably about 5 to 10 μm.
[0021]
A heat sink 23 projects from the surface 4a of the sensor unit 4A so as to partition the space between the heating element 20 (strictly, the temperature sensor 21A) and the ambient temperature detection means 22. The heat sink 23 is formed in a flat plate shape (or cylindrical shape) having an appropriate plate thickness with a metal having good heat dissipation characteristics, for example, aluminum, crosses the sensor portion 4A, and both side end surfaces are fixed to the hole wall of the through hole 7. Has been. The heat sink 23 preferably has a large heat capacity in order to enhance the heat dissipation effect. In addition, it is preferable to coat | cover the location which contacts the said metal thin film 11 for wiring of the heat sink 23 with an insulating film so that it may not electrically conduct.
[0022]
The plate 5 has the through-hole 7 in the center, and a printed wiring board 30 is fixed in close contact with the surface. This printed circuit board 30 has a hole 30a having the same size as the through hole 7 of the plate 5 in the center, and a wiring pattern 31 is printed on the surface side and is electrically connected to the wiring pattern 31. A plurality of lead pins 32 are projected. The electrode pads 10 of the flow velocity detecting means 8 are electrically connected to the wiring pattern 31 by bonding wires 33, and external lead wires (not shown) are connected to the lead pins 32.
[0023]
The material of the plate 5 is preferably a material having high thermal conductivity, heat resistance, and rigidity in order to serve as a structural material and a heat sink in the same manner as the flow path forming member 6, but is in direct contact with the fluid 2. Not so much corrosion resistance is needed.
[0024]
The flow path forming member 6 includes an elongated plate 36 and two cylinders 37A and 37B joined to both longitudinal ends on the back side of the plate 36. However, the plate 36 and the cylinders 37A and 37B may be formed integrally. The plate body 36 has two through holes (fluid supply ports, fluid discharge ports) 38A and 38B formed at both ends in the longitudinal direction and communicating with the cylinders 37A and 37B, respectively, and these through holes 38A and 38B are connected to each other. An oval recess 39 is formed on the surface side so as to communicate with each other. The recess 39 has a width slightly smaller than the width of the substrate 4 and a depth of about 0.5 to several mm, and a slight space formed between the back surface 4b of the substrate 4 is a flow path of the fluid 2. 3 part 3a is formed.
[0025]
The material of the flow path forming member 6 is preferably a material having high heat conductivity and high heat resistance, corrosion resistance and rigidity in order to serve as a structural material and a heat sink. In addition, in order to apply the flow sensor 1 to a corrosive fluid, it is preferable that all the portions that come into contact with the fluid 2 are made of the same material having corrosion resistance. Preferably it is done. Therefore, in the present embodiment, the plate 5 and the flow path forming member 6 are formed of stainless steel (particularly SUS316L) that is the same material as the substrate 4. Thus, if the board | substrate 4, the plate 5, and the flow-path formation member 6 are formed with stainless steel, it can join by using YAG laser welding etc., without using a dissimilar metal. Stainless steel is relatively excellent in workability and is suitable as a sensor material. However, not only stainless steel but also materials having high thermal conductivity such as sapphire and ceramics can be used because the heat transfer in the surface direction can be reduced if they are formed so thin. Note that the thermal conductivities of stainless steel, sapphire, and ceramics at 300 K are 16.0, 46.0, and 36.0 [W / m · K], respectively, depending on their compositions.
[0026]
FIG. 3 is a diagram showing a constant temperature difference circuit of the flow sensor 1. In the figure, a heating element 20, an ambient temperature detecting means 22 and three fixed resistors R1, R2, R3 form a bridge circuit, and this and an operational amplifier (OP1) constitute a constant temperature difference circuit. OP1 takes the midpoint voltage of the bridge circuit, resistor R1 and heating element 20 as an inverting input, and the midpoint voltage of resistors R2 and R3 as a non-inverting input. The output of OP1 is commonly connected to one ends of resistors R1 and R2. The resistance values of the resistors R1, R2, and R3 are set so that the heating element 20 always has a constant temperature higher than the ambient temperature detecting means 22.
[0027]
FIG. 4 is a diagram showing a sensor output circuit of the flow sensor 1. In the figure, two temperature sensors 21A and 21B and two fixed resistors R4 and R5 form a bridge circuit, and this and OP2 constitute a sensor output circuit.
[0028]
In such a flow sensor 1, the fluid 2 is moved in the direction of the arrow in FIG. 2 in a state where the heating element 20 is heated to a certain higher temperature than the ambient temperature by energizing the bridge circuit of the constant temperature difference circuit shown in FIG. When flowed, the sensor unit 4A is deprived of heat in proportion to its flow rate by the fluid 2, so that the heating element 20 is also deprived of heat and the resistance value decreases. For this reason, although the equilibrium state of the bridge circuit is broken, a voltage corresponding to the voltage generated between the inverting input and the non-inverting input is applied to the bridge circuit by OP1, so heat is generated so as to compensate for the heat taken away by the fluid 2. The calorific value of the body 20 increases. As a result, when the resistance value of the heating element 20 increases, the bridge circuit returns to the equilibrium state. Therefore, since a voltage corresponding to the flow velocity is applied to the bridge circuit in an equilibrium state, the voltage between the terminals of the heating element 20 among the voltages applied to the bridge circuit is output as a voltage output. Can be used.
[0029]
When the fluid 2 takes the heat of the heating element 20, a temperature difference is generated between the temperature sensor 21A located on the upstream side of the heating element 20 and the temperature sensor 21B located on the downstream side, so that the sensor output circuit shown in FIG. The voltage difference or resistance value difference is detected, and the flow speed or flow rate can be measured from the relationship between the previously corrected flow rate or flow rate and the voltage difference or resistance value difference.
[0030]
In such a flow sensor 1, the flow velocity detection means 8 and the ambient temperature detection means 22 are provided on the surface of the substrate 4 made of a thin plate-like body that is opposite to the surface that contacts the fluid 2, that is, the surface 4 a. Therefore, the flow velocity detection means 8, the electrode pad 10, the metal thin film 11 for wiring, and the ambient temperature detection means 22 do not corrode or deteriorate due to direct contact with the fluid 2, or dust or the like adheres to the semiconductor. It can also be used to measure corrosive gases and liquids used in manufacturing equipment and the like, and the reliability and durability of the sensor can be improved.
[0031]
Further, since the substrate 4 is formed in a thin plate-like body with stainless steel having a low thermal conductivity, there is little heat conduction in the direction parallel to the surface, and the thickness direction of the substrate 4, that is, the fluid 2 and the flow velocity detecting means 8. The heat conduction between them is good, and the responsiveness can be improved. Stainless steel is excellent in heat resistance, corrosion resistance, workability and rigidity, and is suitable as a sensor material.
[0032]
Further, since the heat sink 23 is provided between the heating element 20 (strictly, the upstream temperature sensor 21A) and the ambient temperature detection means 22, the heating element 20 and the ambient temperature detection means 22 are thermally insulated. Measurement accuracy can be improved. That is, when the heat sink is not used as shown in FIG. 5A, when the heating element 20 is heated, the temperature of the substrate 4 rises due to the heat, so the temperature of the ambient temperature detection means 22 also rises due to heat conduction. This temperature rise becomes a measurement error and the temperature of the fluid 2 cannot be measured accurately.
[0033]
On the other hand, if a heat sink 23 is provided between the heating element 20 and the ambient temperature detection means 22 as shown in FIG. 5B, even if the temperature of the substrate 4 rises due to heating of the heating element 20, the heat Is transmitted to the heat sink 23 and dissipated by being dissipated to the outside, so that almost no heat is transmitted from the heat sink 23 to the ambient temperature detecting means 22 side, and the temperature rise of the ambient temperature detecting means 22 is suppressed. Therefore, the ambient temperature detection means 22 measures the temperature of the fluid 2 with high accuracy. In this case, if the heat capacity of the heat sink 23 is increased, the heat dissipation effect is also large. Therefore, the heat conducted from the heating element 20 to the substrate 4 is effectively dissipated, and the thermal influence on the ambient temperature detecting means 22 is further increased. Can be reduced. Reference numeral 40 denotes an isotherm.
[0034]
Incidentally, when an experiment was conducted with and without the heat sink 23, when the heating element 20 was heated to a predetermined temperature, the temperature of the ambient temperature detection means 22 increased by 5 ° C when the heat sink 23 was not provided. On the other hand, when the heat sink 23 was provided, the temperature of the ambient temperature detecting means 22 hardly increased.
[0035]
FIGS. 6A, 6B, and 6C are a front view, a cross-sectional view, and a rear view showing another embodiment of the present invention. Components identical to those shown in FIGS. 1 and 2 are denoted by the same reference numerals, and description thereof will be omitted as appropriate.
[0036]
In this embodiment, a pipe that forms the flow path 3 of the fluid 2 is used as the flow path forming member 41, a sensor mounting hole 42 is formed in the flow path forming member 41, and a header type flow is formed in the sensor mounting hole 42. A sensor 43 is attached so that the back surface of the substrate 4 is brought into contact with the fluid 2.
[0037]
The flow sensor 43 includes a case 45 with a hook formed in a cup shape, the substrate 4 covering the back opening 46 of the case 45, a plurality of electrodes 50 incorporated in the case 45, and the like. A case 45 is fitted in the sensor mounting hole 42 of the flow path forming member 41 together with a seal member such as an O-ring, and is fixed by a screw, an adhesive, or the like. The rear opening 46 is formed in an oval shape that is long in the flow direction of the fluid 2.
[0038]
The substrate 4 is formed into a thin plate-like body of stainless steel, and the flow velocity detection means 8, the electrode pad 10, the wiring metal thin film 11, the ambient temperature detection means 22 and the heat sink 23 shown in FIG. It is provided via a membrane (not shown). The substrate 4 is not limited to a square, but may be another shape such as an oval.
[0039]
The case 45 is made of stainless steel, is attached to the sensor mounting hole 42 of the flow path forming member 41, and a flange 45a is joined to the outer peripheral surface of the flow path forming member 41 by YAG laser welding or the like. The back surface of the case 45 and the back surface of the substrate 4 form the same surface as the inner wall surface 41 a of the flow path forming member 41 and constitute a part of the flow path 3.
[0040]
The electrode 50 includes a metal frame 51 in which a plurality of terminal pins 52 are sealed with hermetic glass 53, and one end of each terminal pin 52 is brazed to the electrode pad 10 of the metal thin film 11 for wiring. Connected by. It is also possible to connect to the electrode pad 10 using a wire bond without using such a metal frame 51.
[0041]
In the flow sensor 43 having such a structure, a sensor mounting hole 42 is formed in the flow path forming member 41, the flow sensor 43 is fitted and fixed in the sensor mounting hole 42, and the back surface of the substrate 4 is made fluid 2. Since it is only necessary to make it contact, it is not necessary to use a special apparatus, components, etc., and can be easily installed.
[0042]
Further, since the heat sink 23 is provided, the thermal influence on the ambient temperature detection means 22 can be reduced and prevented as in the above-described embodiment, and the measurement accuracy of the sensor can be improved.
[0043]
The present invention is not limited to the above-described embodiment, and various changes and modifications can be made. For example, in the above-described embodiment, a side-heat type sensor in which the spatial temperature distribution of the fluid 2 caused by the heat from the heating element 20 is biased by the flow and is detected by the two temperature sensors 21A and 21B. However, the present invention is not limited to this, and a self-heating type sensor that detects a change in electric power or a change in resistance due to the heat 2 deprived of heat by the fluid 2 and detects a flow rate or a flow velocity is used. May be.
Further, although two temperature sensors 21A and 21B are used, one may be used. Furthermore, two ambient temperature detecting means 22 may be used and arranged to face each other in the flow direction of the fluid 2 or in a direction orthogonal to the flow direction.
[0044]
【The invention's effect】
As described above, according to the flow sensor of the present invention, the heat transmitted from the flow velocity detection means to the substrate is radiated by the heat sink, so that the ambient temperature detection means is prevented from rising due to heat conduction. And the measurement accuracy of the sensor can be improved.
In addition, since it is only necessary to project a heat sink on the substrate, the structure is simple and can be easily manufactured.
In addition, since the flow velocity detection means and the ambient temperature detection means do not come into direct contact with the fluid, the measurement of liquid or corrosive gas can be supported by selecting the substrate material, providing a highly reliable and durable sensor. can do.
[0045]
In addition, examples of the material of the substrate include stainless steel, sapphire, ceramics, etc. Among them, stainless steel is a particularly suitable material in terms of corrosion resistance, workability, thermal conductivity and rigidity, and also has corrosion resistance. In particular, sapphire is suitable when it is necessary to increase it. The thickness of the substrate is preferably as thin as possible in order to improve the heat conduction between the fluid and the flow velocity detection means and reduce the heat conduction in the lateral direction in the substrate. It is necessary to decide in consideration of external factors in manufacturing such as strength and handling. For this reason, in the case of stainless steel, about 50-150 micrometers is optimal.
[Brief description of the drawings]
FIGS. 1A, 1B, and 1C are a front view, a cross-sectional view, and a rear view showing an embodiment of a flow sensor according to the present invention.
FIG. 2 is a front view of a sensor unit.
FIG. 3 is a diagram showing a constant temperature difference circuit of a flow sensor.
FIG. 4 is a diagram showing a sensor output circuit.
FIGS. 5A and 5B are diagrams for explaining the effect of the present invention, in which FIG. 5A is a diagram when no heat sink is provided, and FIG. 5B is a diagram when a heat sink is provided.
FIG. 6 is a front view, a sectional view, and a rear view showing another embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Flow sensor, 2 ... Fluid, 3 ... Flow path, 4 ... Board | substrate, 4A ... Sensor part, 5 ... Plate, 6 ... Flow path formation member, 8 ... Flow-rate detection means, 20 ... Heat generating body (heater), 21A, 21B ... Temperature sensor, 22 ... Ambient temperature detection means, 23 ... Heat sink, 41 ... Flow path forming member, 43 ... Flow sensor, 45 ... Case.

Claims (2)

In a flow sensor having a flow path through which a fluid flows,
The flow path is formed by a thin plate-like substrate formed of any one of stainless steel and sapphire, and a flow path forming member joined to the substrate.
The flow path forming member forms a recess smaller than the substrate on the surface bonded to the substrate,
The flow path includes a space formed between the substrate and the recess is formed with a fluid supply port and fluid outlet communicating with the space,
The substrate includes a flow rate detection unit and an ambient temperature detection unit including a heating element provided on a surface opposite to the flow path side of the substrate, and a space between the flow rate detection unit and the ambient temperature detection unit. And a heat sink projecting on the opposite side of the passage,
The flow sensor, wherein the flow velocity detection means, the ambient temperature detection means, and the heat sink are provided on the same substrate . The flow sensor according to claim 1,
The flow sensor, wherein the flow path forming member is formed of any one of stainless steel, sapphire, and ceramics.

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