JP2005233693A - Flow velocity sensor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a flow velocity sensor measuring the flow velocity of fluid with a simple constitution. <P>SOLUTION: This flow velocity sensor has: an approximately U-shaped projection part 13 projecting toward the inside of a pipe 12 wherein the fluid passes; a fluid temperature sensor 14 bonded and arranged onto the upstream side on the surface of a recessed part constituting the projection part 13; a fluid flow velocity sensor 16 bonded and arranged onto the bottom surface of the recessed part separately from the fluid temperature sensor 14; and a heating resistor 18 laminated and arranged on the fluid flow velocity sensor 16. The interval between the projection part 13 and the fluid temperature sensor 14, the interval between the projection part 13 and the fluid flow velocity sensor 16, and the interval between the fluid flow velocity sensor 16 and the heating resistor 18 are bonded respectively with an adhesive 20 containing silver. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a flow velocity sensor for measuring the flow velocity of the fluid while compensating for the influence of the temperature of the fluid.

  2. Description of the Related Art Conventionally, a thermal flow meter that measures a flow rate, a flow velocity, and the like while compensating for an influence due to the temperature of a fluid is known.

  As shown in FIG. 5, in the thermal flow meter 100 disclosed in Patent Document 1, a bridge circuit 110 includes a fluid flow rate temperature sensor 102, a fluid temperature temperature sensor 104, and two resistors 106 and 108. The fluid flow rate temperature sensor 102 and the fluid temperature temperature sensor 104 are connected to the input terminal side of the differential amplifier circuit 112, and the transistor 114 is connected to the output terminal side of the differential amplifier circuit 112. .

  A heating resistor 116 is connected to the emitter side of the transistor 114, and a driving power source and resistors 106 and 108 (not shown) are connected to the collector side.

  In this case, when a fluid (not shown) passes in the vicinity of the fluid flow rate temperature sensor 102 and the fluid temperature temperature sensor 104 in a state where a predetermined voltage is applied to the bridge circuit 110 from the drive power supply, the fluid flow rate sense is caused by the fluid. The temperature sensor 102 and the fluid temperature temperature sensor 104 are cooled, and the resistance value Rs of the fluid flow rate temperature sensor 102 and the resistance value Rh of the fluid temperature temperature sensor 104 change.

  Here, the differential amplifier circuit 112 and the transistor 114 amplify the voltage difference (differential voltage) generated in the fluid flow rate temperature sensor 102 and the fluid temperature temperature sensor 104, and the amplified differential voltage is The heating resistor 116 is applied to the heating resistor 116 to heat the heating resistor 116.

  As a result, the heating resistor 116 heats the fluid flow rate temperature sensor 102 until the temperature difference between the fluid flow rate temperature sensor 102 and the fluid temperature temperature sensor 104 becomes constant. On the other hand, the differential voltage is output from the thermal flow meter 100 as a signal indicating the flow rate.

  Further, in the thermal type flow meter disclosed in Patent Document 2, a metal made of an electric resistor is formed by a circuit pattern on the fluid temperature temperature sensor and the fluid flow rate temperature sensor, and heat is generated by the current flowing in the circuit pattern. The fluid temperature temperature sensor and the fluid flow rate temperature sensor are heated.

Japanese Patent Laid-Open No. 6-82286 (FIG. 1) JP 2002-168668 A (FIG. 1)

  However, in Patent Document 1, since the heat generation amount of the heating resistor 116 varies depending on the differential voltage output from the differential amplifier circuit 112 and the transistor 114, it is necessary to adjust the heat generation amount. Thereby, there existed a problem that the responsiveness of the thermal type flow meter 100 deteriorated or lacked stability.

  Further, since the thermal flow meter 100 is configured as a closed loop circuit that feeds back the differential voltage to the heating resistor 116, the circuit configuration becomes complicated and the manufacturing cost may increase.

  On the other hand, in Patent Document 2, there is a problem that an error occurs in the output of the thermal flow meter when the fluid flow rate temperature sensor is heated.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a flow rate sensor that can measure the flow rate of a fluid with a simpler configuration.

  The flow velocity sensor according to the present invention includes a first temperature detection unit joined to a pipe through which a fluid passes, a heat generation unit stacked on the first temperature detection unit, and the first temperature detection unit spaced apart from the first temperature detection unit. A second temperature detecting means joined to a pipe; and an output means connected to the first temperature detecting means and the second temperature detecting means, wherein the heat generating means includes the first temperature detecting means. The first temperature detection means outputs a first signal based on its own temperature, and the second temperature detection means outputs a first signal based on the temperature of the fluid flowing in the pipe line. The output means outputs a third signal indicating the flow velocity of the fluid based on a difference between the first signal and the second signal (the invention according to claim 1). ).

  In this case, since the first temperature detection means and the second temperature detection means are joined to the pipe line, the response of the first signal and the second signal when the fluid passes through the pipe line Can be improved.

  The first signal is composed of a component indicating the flow velocity of the fluid and a component indicating the temperature of the fluid, and the second signal is a signal indicating the temperature of the fluid. By taking the difference between the first signal and the second signal, the influence of the temperature of the fluid can be offset. Therefore, the third signal is a signal indicating the flow velocity of the fluid. Therefore, the flow rate sensor can measure the flow rate with a simple circuit configuration.

  In addition, since the first temperature detection means, the second temperature detection means, and the heat generation means are disposed apart from each other in the pipeline, the first temperature is detected from the second temperature detection means and the heat generation means. A thermal influence on the detection means can be avoided.

  Further, unlike the thermal flow meter according to the prior art, the flow rate sensor heats the second temperature detection unit with the predetermined amount of heat using the heat generation unit, so that the circuit configuration is further simplified, and the flow rate sensor The manufacturing cost of the sensor can be reduced.

  Here, the first temperature detection means and the pipe line, the first temperature detection means and the heat generation means, and the second temperature detection means and the pipe line are joined by an adhesive containing silver. It is preferable (the invention according to claim 2). Thereby, thermal conductivity and electrical insulation performance between the first temperature detecting means and the pipe line, between the first temperature detecting means and the heat generating means, and between the second temperature detecting means and the pipe line are improved. To do.

  In particular, since the first temperature detecting means and the heat generating means are electrically insulated, the error of the first signal due to the self-heating of the first temperature detecting means can be reduced. In addition, since the amount of heat generated from the heat generating means is transmitted to the fluid via the first temperature detecting means and the pipe line, it is possible to improve the thermal efficiency of the first temperature detecting means and to reduce the power consumption. Can drive the flow rate sensor.

  Further, the first temperature detecting means and the second temperature detecting means are temperature sensitive resistors configured as separate sides of a bridge circuit, and the heat generating means is a first voltage detecting means by a predetermined voltage. Preferably, the output means is a differential amplifier circuit that outputs a differential output between the first signal and the second signal as the third signal ( Invention of Claim 3).

  In this case, it is preferable that correction means for correcting the third signal is connected in parallel with the second temperature detection means (the invention according to claim 4).

  Further, it is preferable that the second temperature detection means is arranged on the upstream side of the pipe line, and the first temperature detection means and the heat generating means are arranged on the downstream side of the pipe line. invention).

  Further, the first temperature detecting means, the second temperature detecting means, and the heat generating means may be arranged outside the pipe line (the invention according to claim 6), or from the pipe surface to the pipe. You may arrange | position in the recessed part surface of the protrusion part which protrudes toward the inner side of a channel | path (invention of Claim 7), and may arrange | position in contact with the said fluid inside the said pipe line (invention 8). Described invention).

  As described above, according to the present invention, since the first temperature detecting means and the second temperature detecting means are joined to the pipe line, the first signal and the second signal when the fluid passes through the pipe line. Responsiveness can be improved. Further, the first signal is composed of a component indicating the flow velocity of the fluid and a component indicating the temperature of the fluid, and the second signal is a signal indicating the temperature of the fluid. By taking the difference between the signal and the second signal, the influence of the temperature of the fluid can be offset. Therefore, the third signal is a signal indicating the flow velocity of the fluid. Therefore, the flow rate sensor can measure the flow rate with a simple circuit configuration.

  In addition, since the first temperature detection means, the second temperature detection means, and the heat generation means are disposed apart from each other in the pipeline, the first temperature is detected from the second temperature detection means and the heat generation means. A thermal influence on the detection means can be avoided.

  Furthermore, unlike the thermal flow meter according to the prior art, the flow rate sensor heats the second temperature detection unit with a predetermined amount of heat using a heat generation unit, so that the circuit configuration is further simplified, and the flow rate sensor Manufacturing costs can be reduced.

  A preferred embodiment of the flow rate sensor according to the present invention will be described below with reference to the accompanying drawings.

  The flow velocity sensor 10 according to the present embodiment includes a substantially U-shaped protruding portion 13 that protrudes toward the inside of a pipe 12 through which fluid passes in the direction of the arrow in FIG. A fluid temperature sensor (second temperature detecting means) 14 that is joined and arranged on the upstream side (left side in the drawing) on the surface of the concave portion constituting the installation portion 13, and the concave portion spaced apart from the fluid temperature sensor 14 A fluid flow rate sensor (first temperature detecting means) 16 joined to the bottom surface of the fluid and a heating resistor (heat generating means) 18 stacked on the fluid flow rate sensor 16.

  The protruding portion 13 and the fluid temperature sensor 14, the protruding portion 13 and the fluid flow rate sensor 16, and the fluid flow rate sensor 16 and the heating resistor 18 are joined by an adhesive 20 containing silver. This adhesive 20 is an adhesive having high electrical insulation and thermal conductivity.

  The pipe line 12 and the protruding portion 13 are made of, for example, stainless steel or resin. By fastening the screw part formed on the side surface of the protruding part 13 and the screw part provided in the hole part 12a of the pipe line 12 shown in FIG. Fixed to. The projecting portion 13 may be configured integrally with the conduit 12.

  The fluid temperature sensor 14 and the fluid flow rate sensor 16 are composed of, for example, a thermistor and a platinum temperature sensor that have substantially the same resistance temperature coefficient and change in resistance value depending on the temperature of the fluid passing through the pipe 12. The heating resistor 18 transmits heat to the fluid flow rate sensor 16, and the heat is radiated from the fluid flow rate sensor 16 to the fluid via the pipe 12. As a result, the temperature of the fluid in the vicinity of the fluid flow rate sensor 16 increases. Accordingly, the fluid temperature sensor 14 is disposed upstream of the fluid flow rate sensor 16 in order to avoid the occurrence of errors due to the temperature rise of the fluid.

  The fluid that passes through the conduit 12 is, for example, water or air.

  In the flow rate sensor 10, as shown in the circuit diagram of FIG. 2, a fluid temperature sensor 14 having a resistance value Rs, a fluid flow rate sensor 16 having a resistance value Rh, a fixed resistor 22 having a resistance value R1, and a resistance value A bridge circuit 28 is constituted by the fixed resistor 24 having R2 and the fixed resistor 26 having a resistance value R4.

  A drive power supply (not shown) is connected to the input terminal 30 of the bridge circuit 28, and the other input terminal 32 is grounded. One end of a fluid temperature sensor 14, a fluid flow rate sensor 16, and a heating resistor 18 having a resistance value R3 is connected to the input terminal 30, and one end of a fixed resistor 26 is connected to the other end of the fluid temperature sensor 14. One end of the fixed resistor 22 is connected to the other end of the fluid flow rate sensor 16. Furthermore, one end of the fixed resistor 24 is connected to the other end of the fixed resistor 26, and the other end of the heating resistor 18 and the fixed resistors 22, 24 is connected to the input terminal 32.

  Furthermore, the other end of the fixed resistor 26 and the output terminal 34 which is the one end of the fixed resistor 24 are connected to one input terminal 38 of a differential amplifier circuit (output means) 36, An output terminal 40 that is the other end and the one end of the fixed resistor 22 is connected to the other input terminal 42 of the differential amplifier circuit 36. In this case, if one of the input terminals 38 and 42 is an inverting input terminal, the other terminal is a non-inverting input terminal.

  Furthermore, a correction resistor (correction means) 44 is connected in parallel with the fluid temperature sensor 14. The correction resistor 44 is a variable resistor, for example.

  The flow velocity sensor 10 according to the present embodiment is configured as described above, and the operation thereof will be described next.

  First, a constant voltage Vcc is applied from the driving power source to the bridge circuit 28 via the input terminal 30. As a result, the voltage Vcc is applied to the heating resistor 18 to supply a constant power, and the heating resistor 18 generates heat based on the power. The heat generated in the heating resistor 18 is transmitted to the fluid flow rate sensor 16 via the adhesive 20 (see FIG. 1). The fluid flow rate sensor 16 increases its temperature due to the heat, and the resistance value Rh decreases and outputs a voltage V10.

  Next, fluid flows in the direction of the arrow from the upstream side to the downstream side of the conduit 12. The fluid temperature sensor 14 is cooled by the fluid via the pipe line 12 and the adhesive 20, and the resistance value Rs increases. Thereby, the fluid temperature sensor 14 detects its own temperature and outputs a voltage V2 (second signal) indicating the temperature and the resistance value Rs.

  On the other hand, the fluid flow rate sensor 16 is cooled by the fluid via the pipe line 12 and the adhesive 20 so that its own temperature decreases and the resistance value Rh increases. Then, the fluid flow rate sensor 16 outputs a voltage V1 (first signal) corresponding to the lowered temperature.

  The voltages V1 and V2 are input to the differential amplifier circuit 36 through the output terminals 34 and 40 and the input terminals 38 and 42, and the differential amplifier circuit 36 has a differential voltage (V1−V1) which is a difference between the voltages V1 and V2. V2) is amplified, and the amplified differential voltage is output from the output terminal 46 as the output voltage V3 (third signal).

  In this case, the voltage V1 includes a voltage component indicating the temperature of the fluid and a voltage component indicating the flow velocity of the fluid, and the voltage V2 includes a voltage component indicating the temperature of the fluid. Therefore, when the differential voltage (V1-V2) is generated in the differential amplifier circuit 36, the influence of the fluid temperature is offset. Therefore, the output voltage V3 is composed of only a voltage component indicating the flow velocity of the fluid and is a signal indicating the flow velocity of the fluid.

  Here, regarding the fluid flow rate sensor 16, there is a proportional relationship between the temperature detected by the fluid flow rate sensor 16 and the flow rate of the fluid. Therefore, a proportional relationship is established between the output voltage V3 and the fluid flow velocity.

  Further, when the resistance of the correction resistor 44 is changed for the purpose of improving the temperature characteristics of the fluid flow rate sensor 16, the resistance value of the parallel circuit composed of the fluid flow rate sensor 16 and the correction resistor 44 is changed, and the voltage V1 is changed. . Thereby, the output voltage V3 of the differential amplifier circuit 36 can be easily corrected.

  As described above, in the flow rate sensor 10 according to the present embodiment, the fluid temperature sensor 14 and the fluid flow rate sensor 16 are directly joined to the pipe line 12 via the adhesive 20, so that the fluid flows in the pipe line 12. When passing, the responsiveness of the voltages V1 and V2 can be improved. Further, since the differential amplifier circuit 36 can cancel the influence of the temperature of the fluid by taking the difference between the voltages V1 and V2, the voltage V3 output from the differential amplifier circuit 36 is It becomes a signal indicating the flow rate of. Therefore, the flow velocity sensor 10 according to the present embodiment can measure the flow velocity with a simple circuit configuration.

  In addition, the fluid flow rate sensor 16 can be heated by a constant amount of heat only by applying a constant voltage Vcc to the heating resistor 18, so that it is compared with the thermal flow meter 100 according to the prior art (see FIG. 5). The control circuit for the heating resistor 18 is simplified, and the flow rate sensor 10 can be manufactured at a low cost. Further, in the flow rate sensor 10, since the power consumption of the heating resistor 18 and the flow rate of the fluid are irrelevant, the flow rate measurement is more stable than the thermal flow meter 100 (see FIG. 5). Can be done.

  In addition, since the fluid temperature sensor 14 and the fluid flow rate sensor 16 are separated and joined on the pipe 12, it is possible to avoid a thermal influence from the heating resistor 18 on the fluid temperature sensor 14.

  Further, an adhesive 20 containing silver is used between the fluid temperature sensor 14 and the pipe 12, between the fluid flow rate sensor 16 and the pipe 12, and between the fluid flow rate sensor 16 and the heating resistor 18. Since they are joined, thermal conductivity and electrical insulation performance between them can be improved.

  In particular, since the fluid flow rate sensor 16 and the heating resistor 18 are electrically insulated by the adhesive 20, the error of the voltage V1 due to self-heating of the fluid flow rate sensor 16 can be reduced. In addition, the amount of heat generated from the heating resistor 18 is transmitted to the fluid via the fluid flow rate sensor 16 and the conduit 12, so that it is possible to improve the thermal efficiency of the fluid flow rate sensor 16, and at low power. The flow rate sensor 10 can be driven.

  Furthermore, since the fluid temperature sensor 14 and the fluid flow rate sensor 16 are disposed on the input terminal 30 side of the bridge circuit 28, the influence of the temperature of the fluid can be easily compensated by the correction resistor 44, and the flow velocity The performance of the sensor 10 can be improved.

  Next, flow velocity sensors 50 and 52 according to a modification of the present embodiment will be described with reference to FIGS. In addition, about the component same as the flow velocity sensor 10, the same referential mark is attached | subjected and the detailed description is abbreviate | omitted.

  The flow rate sensor 50 is different from the flow rate sensor 10 in that the fluid temperature sensor 14 and the fluid flow rate sensor 16 are joined to the outside of the pipe line 12 via the adhesive 20.

  In this case, since the fluid temperature sensor 14 and the fluid flow rate sensor 16 are directly joined to the pipe 12, the flow rate sensor 50 can be attached very easily.

  On the other hand, in the flow rate sensor 52, the fluid temperature sensor 14 is fixed to the hole 12b provided in the pipe line 12 via the adhesive 20, and the fluid flow rate sensor 16 is fixed to the other hole 12c via the adhesive 20. This is different from the flow rate sensor 10.

  In this case, since the fluid temperature sensor 14 and the fluid flow rate sensor 16 are in contact with the fluid in the pipe 12, the responsiveness of the voltage V2 output from the fluid temperature sensor 14 and the voltage V1 output from the fluid flow rate sensor 16 is satisfied. It is possible to improve the thermal efficiency of the fluid flow rate sensor 16 from the heating resistor 18.

  In the present embodiment, the fluid flow rate sensor 16 and the heating resistor 18 are joined via the adhesive 20, but the fluid flow rate sensor 16 and the heating resistor 18 are integrally configured as a laminate. Of course, you may do.

  Furthermore, in the present embodiment, the fluid temperature sensor 14 and the fluid flow rate sensor 16 are disposed on the input terminal 30 side of the bridge circuit 28, but may be disposed on the input terminal 32 side (ground side). Of course.

  In addition, the flow velocity sensor according to the present invention is not limited to the above-described embodiment, and it is needless to say that various configurations can be adopted without departing from the gist of the present invention.

It is sectional drawing of the flow velocity sensor which concerns on this Embodiment. It is explanatory drawing which shows the circuit structure of the flow velocity sensor which concerns on this Embodiment. It is sectional drawing which shows the flow rate sensor which concerns on the modification of this Embodiment. It is sectional drawing which shows the flow rate sensor which concerns on the modification of this Embodiment. It is explanatory drawing which shows the circuit structure of the thermal type flow meter which concerns on a prior art.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10, 50, 52 ... Flow rate sensor 12 ... Pipe line 12a, 12b, 12c ... Hole part 13 ... Projection part 14 ... Fluid temperature sensor 16 ... Fluid flow rate sensor 18 ... Heating resistor 20 ... Adhesive 22, 24, 26 ... Fixed resistor 28... Bridge circuit 30, 32, 38, 42 ... Input terminal 34, 40, 46 ... Output terminal 36 ... Differential amplifier circuit 44 ... Correction resistor

Claims (8)

A first temperature detecting means joined to a conduit through which a fluid passes, a heat generating means stacked on the first temperature detecting means, and a second joined to the conduit apart from the first temperature detecting means. Temperature detection means; output means connected to the first temperature detection means and the second temperature detection means;
With
The heat generating means heats the first temperature detecting means with a predetermined amount of heat,
The first temperature detecting means outputs a first signal based on its own temperature,
The second temperature detecting means outputs a second signal based on the temperature of the fluid flowing in the pipe;
The output means outputs a third signal indicating a flow speed of the fluid based on a difference between the first signal and the second signal. The flow rate sensor according to claim 1,
The first temperature detection means and the pipe line, the first temperature detection means and the heat generation means, and the second temperature detection means and the pipe line are joined by an adhesive containing silver. A flow rate sensor characterized by The flow rate sensor according to claim 1,
The first temperature detection means and the second temperature detection means are temperature sensitive resistors configured as separate sides of a bridge circuit,
The heat generating means is a resistor that heats the first temperature detecting means with the predetermined amount of heat by a predetermined voltage,
The flow rate sensor, wherein the output means is a differential amplifier circuit that outputs a differential output of the first signal and the second signal as the third signal. The flow rate sensor according to claim 3,
A flow rate sensor, wherein the correction means for correcting the third signal is connected in parallel with the second temperature detection means. The flow rate sensor according to claim 1,
The flow rate sensor characterized in that the second temperature detecting means is arranged on the upstream side of the pipe line, and the first temperature detecting means and the heat generating means are arranged on the downstream side of the pipe line. The flow rate sensor according to claim 1,
The flow rate sensor, wherein the first temperature detection means, the second temperature detection means, and the heat generation means are arranged outside the pipe line. The flow rate sensor according to claim 6, wherein
The first temperature detecting means, the second temperature detecting means, and the heat generating means are arranged on a concave surface of a projecting portion that protrudes from the pipe surface toward the inside of the pipe. A flow rate sensor. The flow rate sensor according to claim 1,
The first temperature detecting means and the second temperature detecting means are disposed in contact with the fluid inside the pipe line.

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