JP3715920B2 - Thermal flow meter - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a thermal flow meter that measures a flow rate using a hot wire. More specifically, the present invention relates to a thermal type flow meter that stabilizes measurement output by reducing fluid disturbance generated in a flow path.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, as one type of thermal flow meter that measures a flow rate using a hot wire, there is one that uses a measurement chip manufactured by a semiconductor micromachining processing technique as a sensor unit. An example of this type of thermal flow meter is shown in FIG. In the thermal flow meter 101 of FIG. 23, the fluid to be measured that has flowed into the inlet port 102 is rectified by the rectifying mechanism 103 and then flows out from the outlet port 105 via the measurement flow path 104. In order to measure the flow rate of the measurement fluid, the measurement chip 111 connected to the electric circuit 106 is exposed to the measurement flow path 104.
[0003]
Here, as shown in FIG. 24, the measurement chip 111 is a silicon chip 116, an upstream temperature sensor 112, a heater 113, a downstream temperature sensor 114, an ambient temperature sensor 115 (the above-mentioned sensors 112 to 115 are “heat rays”. Etc.) are subjected to semiconductor micromachining processing technology.
[0004]
In the thermal flow meter 101, in the measurement chip 111 of FIG. 24, six electrodes D1, D2, D3, D4, D5, and D6 are provided on the silicon chip 116, and an upstream temperature sensor 112, a heater 113, and a downstream temperature sensor are provided. 114, each of the ambient temperature sensors 115 and the electric circuit 106 are connected by wire bonding (W in FIG. 23) using six electrodes D1 to D6.
[0005]
In such a thermal flow meter 101, when the fluid to be measured does not flow into the measurement flow path 104, the temperature distribution of the measurement chip 111 in FIG. On the other hand, when the fluid to be measured flows through the measurement flow path 104, the temperature of the upstream temperature sensor 112 decreases and the temperature of the downstream temperature sensor 114 increases, so the symmetry of the temperature distribution of the measurement chip 111 in FIG. Will collapse according to the flow rate of the fluid to be measured. At this time, the degree of the collapse appears as a difference in resistance value between the upstream temperature sensor 112 and the downstream temperature sensor 114, so that the flow rate of the fluid to be measured can be measured via the electric circuit 106.
[0006]
Here, vacuum suction is used for handling during semiconductor chip mounting. And confirmation of adsorption | suction was conventionally performed with the pressure sensor. However, in recent years, semiconductor chips have become smaller and smaller. For this reason, for example, in a 0.5 mm square chip, a suction orifice (nozzle) having a diameter of 0.5 mm or 0.3 mm is used. As a result, there was no difference in the pressure in the orifice between adsorption and non-adsorption, and the pressure sensor could not confirm adsorption. For this reason, proposals have been made to confirm adsorption by detecting the flow rate of air flowing through the orifice.
[0007]
[Problems to be solved by the invention]
However, the thermal flow meter 101 shown in FIG. 23 described above has a problem of low response (1-2 sec). This is because the rectifying mechanism 103 cannot eliminate the turbulent flow generated in the measurement flow path 104, and an integration process is performed on the output signal so that the influence of the turbulent flow is not output to the output signal. It is thought that it is from. Further, there is a problem that the thermal flow meter 101 shown in FIG. 23 is too large to be used for confirmation of adsorption. For this reason, it is difficult to use the thermal flow meter 101 for confirmation of adsorption.
[0008]
For this reason, the present applicant has proposed, in Japanese Patent Application No. 2000-368801, a high-speed response (50 ms) and small thermal flow meter in order to solve the problems of response and size. Since this thermal flow meter is small and excellent in responsiveness, it was suitable for use in confirmation of adsorption. However, the thermal flow meter proposed by the present applicant in Japanese Patent Application No. 2000-368801 has a problem that the influence of fluid turbulence in the flow path increases as the measured flow rate increases. That is, when the measurement flow rate is increased, a problem arises that the measurement output becomes unstable due to fluid disturbance in the flow path. For this reason, it is difficult to accurately perform adsorption confirmation even with the thermal flow meter proposed in Japanese Patent Application No. 2000-368801.
[0009]
Therefore, the present invention has been made to solve the above-described problems, and an object of the present invention is to provide a thermal flow meter that can stably obtain a measurement output even when the measurement flow rate is large. .
[0010]
[Means for Solving the Problems]
The thermal flow meter according to the present invention, which has been made to solve the above problems, has a thermal flow rate provided with a bypass flow path for the sensor flow path in addition to the sensor flow path provided with a hot wire for measuring the flow rate. In the total, a filter is provided between the bypass flow path and the sensor flow path.
[0011]
In this thermal type flow meter, the fluid to be measured that has flowed into the flow meter is divided into a sensor flow path in which a hot wire is installed and a bypass flow path with respect to the sensor flow path. And based on the measurement principle using a heat ray, the flow volume of the fluid under measurement which flows through a sensor flow path, and by extension, the flow volume of the fluid under measurement which flows through the inside of a thermal flow meter are measured. The flow rate range is changed by changing the ratio of the fluid to be measured that is divided into the sensor flow path and the bypass flow path, specifically, by changing the cross-sectional area of the bypass flow path.
[0012]
For this reason, when the measurement flow rate increases, the flow rate of the fluid to be measured flowing through the bypass channel increases. As a result, the flow of the fluid to be measured in the bypass channel is disturbed. Then, under the influence of the disturbance of the flow of the fluid under measurement in the bypass channel, the flow of the fluid under measurement flowing through the sensor channel is also disturbed. As a result, the measurement output becomes unstable.
[0013]
However, this thermal flow meter is provided with a filter between the bypass flow path and the sensor flow path. For this reason, the fluid to be measured flows into the sensor flow path after passing through the filter. Thereby, the flow of the fluid to be measured flowing into the sensor flow path is adjusted. In other words, even if the flow of the fluid to be measured flowing into the bypass flow path is disturbed, the flow of the fluid to be measured flowing into the sensor flow path is adjusted by the filter provided between the bypass flow path and the sensor flow path. . Therefore, the measurement output is stabilized.
[0014]
In the thermal type flow meter according to the present invention, the filter is preferably a laminate of a plurality of meshes. More preferably, the meshes are stacked via a spacer having a predetermined thickness.
[0015]
This is because, by forming a filter by laminating a plurality of meshes, a fluid to be measured whose flow is very arranged can be poured into the sensor flow path. This is because the turbulence of the fluid to be measured decreases every time it passes through a plurality of meshes. Therefore, in order to obtain a larger rectifying effect, it is considered that it is better to overlap each mesh with a predetermined interval than to directly overlap each mesh. Therefore, the mesh is preferably laminated through a spacer having a predetermined thickness.
[0016]
In addition, the thermal flow meter according to the present invention is a thermal flow meter provided with a bypass flow path for the sensor flow path in addition to the sensor flow path provided with a heat wire for measuring the flow rate. It has a rectifying mechanism that regulates the flow of fluid by forming a plurality of flow paths.
[0017]
This thermal flow meter has a rectifying mechanism that regulates the flow of fluid by forming a plurality of channels in the bypass channel. For this reason, the flow of the fluid to be measured in the bypass channel is adjusted. Thereby, the flow of the fluid to be measured in the bypass flow path does not adversely affect the flow of the fluid to be measured in the sensor flow path. Accordingly, since the flow of the fluid to be measured flowing through the sensor flow path is stabilized, the measurement output is stabilized.
[0018]
In the thermal type flow meter according to the present invention, the rectifying mechanism is preferably a laminate of thin plates having grooves. A plurality of grooves are preferably formed in the thin plate. In addition, when forming a some groove | channel, a groove | channel may be formed only in the single side | surface of a thin plate, and a groove | channel may be formed in both surfaces of a thin plate.
[0019]
A plurality of flow paths are formed in the bypass flow path by laminating thin plates having grooves formed in this manner. That is, the bypass channel is divided into a plurality of small channels. Then, the fluid to be measured flowing into the bypass channel flows through each groove. For this reason, the flow of the fluid to be measured flowing through the bypass channel is adjusted. In addition, by forming a plurality of grooves in one thin plate, the stacked body can be provided with more grooves, and a greater rectifying effect can be obtained.
[0020]
Further, the rectifying mechanism may be a pin formed with a plurality of fins. By providing such a pin in the bypass channel, a plurality of channels are formed in the bypass channel. This is because the flow of the fluid to be measured flowing through the bypass flow path is adjusted.
[0021]
In addition, the thermal flow meter according to the present invention is a thermal flow meter provided with a bypass flow path for the sensor flow path in addition to the sensor flow path provided with a heat wire for measuring the flow rate. And a fluid flowing out from the bypass flow path are joined at an outlet flow path formed in the body.
[0022]
In this thermal flow meter, since the shielding plate is provided, the fluid to be measured that flows out from the sensor flow path and the fluid to be measured that flows out from the bypass flow path merge at the outlet flow path formed in the body. . That is, the fluid to be measured flowing out from the sensor flow path and the fluid to be measured flowing out from the bypass flow path do not merge near the outlet of the sensor flow path. Thereby, the confluence | merging point of a sensor flow path and a bypass flow path is kept away from the heat ray | wire constructed in the sensor flow path. Therefore, since the vortex of the flow generated at the confluence of the sensor flow path and the bypass flow path does not disturb the flow of the fluid to be measured in the sensor flow path, the measurement output is stabilized.
[0023]
Note that the shielding wall has a size that allows the vortex of the flow generated at the confluence point of the sensor flow path and the bypass flow path to keep the confluence point far enough not to affect the flow of the fluid to be measured in the sensor flow path. That's fine. Therefore, the tip of the shielding wall may be located on the upper surface of the outlet channel, or may be located in the center of the outlet channel.
[0024]
Here, it is desirable that the outlet channel is not formed on the same straight line with respect to the bypass channel. This is because when the outlet channel is formed in this way, the above-described effect obtained by providing the shielding wall becomes larger.
[0025]
The shielding wall is preferably formed by laminating a plurality of shielding plates. This is because the groove described above can be formed in the shielding plate. That is, a shielding wall can be formed and a rectifying mechanism can be provided in the bypass channel. Thereby, the influence of the turbulent flow of the fluid to be measured in the Pibus channel on the measurement output when the measurement flow rate increases can be more effectively suppressed.
[0026]
In addition, since the mesh described above is also formed in a thin plate, the above effect is synergistically arranged by arranging the mesh above and arranging the shielding plate (including grooves) below and laminating each of them. Demonstrated. That is, there is almost no disturbance in the flow of the fluid to be measured in the sensor flow path. For this reason, the measurement output is very stable. In addition to the combinations exemplified here, a synergistic effect can be obtained by arbitrarily combining the above-described inventions.
[0027]
In the above-described thermal flow meter according to the present invention, the bypass flow path includes a substrate provided with an electrode for an electric circuit connected to an electric circuit for performing a measurement principle using a hot wire, and a side opening. It is formed by close contact with the body in which the fluid flow path is provided so as to close the side opening, and the sensor flow path includes a measurement chip provided with a heat ray and a heat ray electrode connected to the heat ray. It is desirable to form a groove formed in at least one of the measurement chip and the substrate by bonding the heat ray electrode and the electric circuit electrode and mounting them on the substrate. In the present specification, the “side opening” means an opening that is open on the side of the body (in other words, the surface where the input / output port is not open) and the substrate is mounted.
[0028]
In such a thermal flow meter, when the measurement chip is mounted on the substrate, the heat wire provided on the measurement chip includes a heat wire electrode provided on the measurement chip and an electric circuit electrode provided on the surface of the substrate. Is bonded to an electric circuit for performing a measurement principle using a hot wire. On the other hand, when the substrate is in close contact with the body, a bypass channel is formed inside the body. At this time, since the groove is provided in the substrate or the measurement chip mounted on the substrate, a sensor flow path for the bypass flow path is also formed inside the body. Thereby, the responsiveness improvement and size reduction of a thermal type flow meter are achieved.
[0029]
Then, the fluid to be measured flowing inside the body is divided into the bypass channel and the sensor channel according to the cross-sectional area ratio between the bypass channel and the sensor channel. In this respect, since the heat ray provided in the measurement chip is in a state of being bridged to the sensor flow path, the flow rate of the fluid to be measured flowing through the sensor flow path by the electric circuit for performing the measurement principle using the heat ray, As a result, the flow rate of the fluid to be measured flowing inside the body can be measured. As described above, since no disturbance occurs in the flow of the fluid to be measured in the sensor flow path, a very stable measurement output can be obtained. That is, this thermal flow meter can output a stable measurement result with a high-speed response.
[0030]
Further, the thermal flow meter according to the present invention includes a substrate having a surface provided with an electrode for an electric circuit connected to an electric circuit for performing a measurement principle using a hot wire, a fluid flow path including a side opening and a fluid. A bypass channel formed by close contact with a body in which an outlet channel that is not collinear with the channel is formed so as to close the side opening, and a hot wire connected to the hot wire A sensor flow path formed by a groove provided in at least one of the measurement chip or the substrate by bonding the measurement chip provided with the electrode to the substrate by bonding the electrode for a heat wire and the electrode for an electric circuit; And a filter in which a plurality of meshes are stacked between the bypass flow path and the sensor flow path, and a fluid flowing out from the sensor flow path and a fluid flowing out from the bypass flow path at the outlet flow path. Confluence A shielding wall for, is characterized in that it has a. In particular, it is desirable that the shielding wall is composed of a plurality of shielding plates, and the filter and the shielding wall are provided in one laminate.
[0031]
In this thermal flow meter, a substrate provided with an electrode for an electric circuit connected to an electric circuit for performing a measurement principle using a hot wire is disposed on a body on which a fluid channel having a side opening is formed. A measurement chip provided with a bypass flow path formed by close contact with the side opening and a heat ray and a heat ray electrode connected to the heat ray is provided with a heat ray electrode and an electric circuit electrode. By bonding and mounting on a substrate, a sensor flow path formed by a groove provided in at least one of the measurement chip or the substrate is provided, so that the response is improved and the size is reduced as described above. .
[0032]
Further, the thermal flow meter includes a filter in which a plurality of meshes are stacked between the bypass channel and the sensor channel, a fluid to be measured that flows out from the sensor channel, and a fluid to be measured that flows out from the bypass channel. And a shielding wall for joining the two in the fluid flow path. Thereby, the effect by having provided the above-mentioned mesh and the effect by having provided the shielding wall are synergistically acquired. That is, the flow of the fluid to be measured in the sensor channel is hardly disturbed. Therefore, a very stable measurement output can be obtained. That is, this thermal flow meter can output a stable measurement result with a high-speed response. Moreover, since the mesh (filter) and the shielding wall are provided in one laminated body, the thermal flow meter is not increased in order to obtain a stable measurement output.
[0033]
DETAILED DESCRIPTION OF THE INVENTION
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a most preferred embodiment that embodies a thermal flow meter of the present invention will be described in detail with reference to the drawings. The thermal flow meter according to the present embodiment is suitable for flow rate measurement that requires high-speed response and high sensitivity, for example, suction confirmation in handling during semiconductor chip mounting.
[0034]
(First embodiment)
First, the first embodiment will be described. FIG. 1 shows a schematic configuration of the thermal type flow meter according to the first embodiment. As shown in FIG. 1, the thermal flow meter 1 according to the present embodiment includes a body 41, a sensor substrate 21, and a multilayer filter 50. The sensor substrate 21 is in close contact with the body 41 via the seal packing 48 with screws while the multilayer filter 50 is mounted in the flow path space 44 of the body 41. Thereby, the main flow path M which is a bypass flow path with respect to the sensor flow path S and the sensor flow path S is formed. That is, the thermal flow meter 1 according to the present embodiment is a thermal flow meter including a sensor flow path and a bypass flow path.
[0035]
As shown in FIGS. 2 and 3, the body 41 has a rectangular parallelepiped shape. 2 is a plan view of the body 41, and FIG. 3 is a cross-sectional view taken along line AA in FIG. The body 41 is formed with an inlet port 42 and an outlet port 46 on both end faces. An inlet channel 43 is formed from the inlet port 42 toward the center of the body. Similarly, an outlet channel 45 is formed from the outlet port 46 toward the center of the body. The outlet channel 45 is formed below the main channel M. That is, the outlet channel and the main channel M are not arranged on the same straight line.
[0036]
In addition, a channel space 44 for forming the main channel M and the sensor channel S is formed in the upper portion of the body 41. The cross section of the flow path space 44 has a shape in which both short sides of the rectangle are arcuate (semicircle), and an arcuate convex part 44C is formed at the center. The convex portion 44C is for positioning the multilayer filter 50 or a pin 80 (see the fourth embodiment) described later. A part of the lower surface of the channel space 44 communicates with the inlet channel 43 and the outlet channel 45. That is, the inlet channel 44 and the outlet channel 45 are communicated with the channel space 44 via elbow portions 43A and 45A bent at 90 degrees, respectively. Further, a groove 49 for mounting the seal packing 48 is formed on the upper surface of the body 41 along the outer periphery of the flow path space 44.
[0037]
As shown in FIG. 4, the multilayer filter 50 is obtained by laminating a total of 11 sheets of four types of thin plates. That is, in order from the bottom, the mesh plate 51, the first shielding plates 52, 52, 52, 52, the mesh plate 51, the second shielding plate 53, the mesh plate 51, the second shielding plate 53, the mesh plate 51, and the third shielding. A plate 54 is laminated and bonded. Each of these thin plates 51 to 54 has a thickness of 0.5 mm or less, and each shape is processed (micromachining) by etching. The projected shapes of the thin plates 51 to 54 are the same as the cross-sectional shape of the flow path space 44. As a result, the multilayer filter 50 is mounted in the flow path space 44 without a gap.
[0038]
Here, individual thin plates will be described. First, the mesh plate 51 will be described with reference to FIGS. 5A is a plan view of the mesh plate, FIG. 5B is a cross-sectional view taken along the line AA in FIG. 5A, and FIG. 6 is an enlarged view of the mesh portion. As shown in FIG. 5, the mesh plate 51 is a thin plate having a thickness of 0.3 mm in which mesh portions 51M are formed at both ends. The mesh part 51M has a circular shape with a diameter of 4 mm, and is formed such that the distance between the centers of the holes (diameter 0.2 mm) constituting the mesh is 0.27 mm as shown in FIG. That is, the holes are formed so that the centers of the holes are the vertices of the equilateral triangle. In addition, the thickness of the mesh part 51M is thinner than other parts as shown in FIG.5 (b), The thickness is 0.05-0.1 mm. Further, a shielding part 51C is formed on the mesh part 51M (on the right side in FIG. 5) arranged on the outlet side.
[0039]
Next, the first shielding plate 52 will be described with reference to FIG. 7A is a plan view of the first shielding plate, and FIG. 7B is a cross-sectional view taken along line AA in FIG. 7A. As shown in FIG. 7, the first shielding plate 52 is etched so as to leave the outer peripheral portion 52B and the shielding portion 52C. Thereby, the first shielding plate 52 is formed with a first opening 61 and a second opening 62. In addition, the thickness of the 1st shielding board 52 is 0.5 mm.
[0040]
Next, the second shielding plate 53 will be described with reference to FIG. 8A is a plan view of the second shielding plate, and FIG. 8B is a cross-sectional view taken along line AA in FIG. 8A. As shown in FIG. 8, the second shielding plate 53 is etched so as to leave the outer peripheral portion 53B, the shielding portion 53C, and the central portion 53D. That is, an unprocessed portion is also left in the center of the first shielding plate 52. As a result, a third opening 63, a fourth opening 64, and a second opening 62 are formed in the second shielding plate 53. The thickness of the second shielding plate 53 is also 0.5 mm.
[0041]
Finally, the 3rd shielding board 54 is demonstrated using FIG. 9A is a plan view of the third shielding plate, and FIG. 9B is a cross-sectional view taken along the line AA in FIG. 9A. As shown in FIG. 9, the third shielding plate 54 is etched so as to leave the outer peripheral portion 54B and the shielding portion 54C. That is, by not forming the fourth opening 64 in the second shielding plate 53, the shielding part 53C and the central part 53D are integrated to form the shielding part 54C. As a result, a third opening 63 and a second opening 62 are formed in the third shielding plate 54. Note that the thickness of the third shielding plate 54 is also 0.5 mm.
[0042]
Here, referring back to FIG. 1, a laminated filter 50 in which the mesh plate 51, the first shielding plate 52, the second shielding plate 53, and the third shielding plate 54 are combined and laminated and bonded as shown in FIG. Is attached to the flow path space 44, so that the main flow path M is formed by the first opening 61 provided in the first shielding plate 52. Further, the first communication flow for communicating the inlet flow path 43 with the main flow path M and the sensor flow path S by the mesh portion 51, the first opening portion 61, and the third opening portion 63 provided in each of the thin plates 51 to 54. A path 5 is formed. Three layers of mesh portions 51M are arranged between the main flow path M and the sensor flow path S. The interval between the mesh portions 51M is 0.7 mm, with the mesh plate 51 and the second shielding plate 53 serving as spacers. Thereby, the fluid under measurement whose flow is adjusted every time it passes through each mesh portion 51M can be poured into the sensor flow path S. Furthermore, the mesh part 51 is also arranged at the communication part between the elbow part 43A and the flow path space 44 (main flow path M).
[0043]
Further, by attaching the multilayer filter 50 to the flow path space 44, the main flow path M and the outlet flow path are formed by the mesh portion 51, the first opening portion 61, and the fourth opening portion 64 provided in the thin plates 51 to 54. A second communication flow path 6 that communicates with 45 is formed. Furthermore, a third communication channel 7 that connects the sensor channel S and the outlet channel 45 is formed by the second opening 62 provided in each of the thin plates 51 to 54. A shielding wall 47 is formed between the second communication channel 6 and the third communication channel 7. The shielding wall 47 is constituted by the shielding portions 51C, 52C, 53C, and 54C provided on the thin plates 51, 52, 53, and 54, respectively. The shielding wall 47 serves as a communication portion between the elbow portion 45 </ b> A and the flow path space 44 at the junction of the measured fluid flowing from the sensor flow path S and the measured fluid flowing from the main flow path M. Further, as described above, the outlet channel 45 is disposed below the main channel M.
[0044]
Therefore, the fluid to be measured flowing out from the sensor flow path S and the fluid to be measured flowing out from the main flow path M do not merge near the outlet of the sensor flow path S. That is, the junction point of the sensor flow path S and the main flow path M is kept away from the measurement chip 11 described later. Therefore, the vortex of the flow generated at the junction of the sensor flow path S and the main flow path M does not disturb the flow of the fluid to be measured flowing through the measurement chip 11 in the sensor flow path S.
[0045]
On the other hand, the sensor substrate 21 outputs the measured flow rate as an electrical signal. For this reason, as shown in FIG. 10, the sensor substrate 21 has a groove 23 formed in the center thereof on the surface side (the mounting surface side to the body 41) of the printed circuit board 22 serving as a base. Electric circuit electrodes 24, 25, 26, and 27 are provided on both sides of the groove 23. On the other hand, an electrical circuit composed of electrical elements 31, 32, 33, 34, and the like is provided on the back side of the printed circuit board 22 (see FIG. 1). In the printed circuit board 22, the electric circuit electrodes 24 to 27 are connected to an electric circuit including the electric elements 31 to 34. Further, the measurement chip 11 is mounted on the surface side of the printed circuit board 22 as described later.
[0046]
Here, the measurement chip 11 will be described with reference to FIG. FIG. 11A is a plan view of the measurement chip, and FIG. 11B is a side view of the measurement chip. As shown in FIG. 11, the measurement chip 11 is obtained by performing a semiconductor micromachining processing technique on the silicon chip 12. At this time, the groove 13 is processed and the hot wire electrodes 14, 15, 16 and 17 are provided on both sides of the groove 13. Further, at this time, the temperature sensor hot wire 18 extends from the hot wire electrodes 14 and 15 and is laid over the groove 13, and the flow velocity sensor hot wire 19 extends from the hot wire electrodes 16 and 17. And is installed on the groove 13. Further, in the measurement chip 11, the flow rate sensor hot wire 19 is provided on the downstream side of the sensor flow path S, and the run-up section L of the fluid to be measured F 2 flowing through the sensor flow path S is long. This is for adjusting the flow of the fluid to be measured F2 flowing through the sensor flow path S.
[0047]
Then, the electrodes 14, 15, 16, 17 for the hot wire of the measuring chip 11 are respectively connected to the electrodes 24, 25, 26, 27 (see FIG. 10) for the electric circuit of the sensor substrate 21, solder reflow, conductive adhesive, etc. The measurement chip 11 is mounted on the sensor substrate 21 by bonding at the above. Accordingly, when the measuring chip 11 is mounted on the sensor substrate 21, the temperature sensor hot wire 18 and the flow velocity sensor hot wire 19 provided on the measuring chip 11 are connected to the hot wire electrodes 14 to 17 of the measuring chip 11 and the sensor substrate 21. The electrical circuit electrodes 24 to 27 (see FIG. 10) are connected to an electrical circuit provided on the back side of the sensor substrate 21.
[0048]
When the measurement chip 11 is mounted on the sensor substrate 21, the groove 13 of the measurement chip 11 overlaps with the groove 23 of the sensor substrate 21A. Therefore, as shown in FIG. 1, when the sensor substrate 21 on which the measurement chip 11 is mounted is brought into close contact with the body 41 via the seal packing 48, the sensor substrate 21 and the measurement chip 11 are disposed in the flow path space 44 of the body 41. An elongated sensor flow path S composed of the groove 13 of the measuring chip 11 and the groove 23 of the sensor substrate 21 is formed therebetween. Therefore, in the sensor flow path S, the temperature sensor hot wire 18 and the flow velocity sensor hot wire 19 are provided so as to cross the bridge.
[0049]
Then, the effect | action of the thermal type flow meter 1 which has an above-described structure is demonstrated. In the thermal flow meter 1, as shown in FIG. 1, the fluid to be measured (F in FIG. 1) that flows into the inlet channel 43 via the inlet port 42 flows to the main channel M in the channel space 44. The flow is divided into a flow (F1 in FIG. 1) and a flow into the sensor flow path S (F2 in FIG. 1). Then, the fluids to be measured that have flowed out of the main flow path M and the sensor flow path S merge and flow out of the body 41 from the outlet port 46 via the outlet flow path 45 (F in FIG. 1).
[0050]
Here, the fluid to be measured (F2 in FIG. 1) flowing into the sensor flow path S flows into the sensor flow path S after passing through the three-layer mesh portion 51M in the multilayer filter 50. Further, the fluid to be measured that has flowed out of the main flow path M and the sensor flow path S joins at a point away from the measurement chip 11 by the shielding wall 47. For this reason, the vortex of the flow generated at the merge point does not affect the flow of the fluid to be measured (F2 in FIG. 1) flowing through the sensor flow path S. Therefore, the fluid to be measured in a state in which the flow is very arranged flows through the sensor flow path S.
[0051]
Then, the fluid to be measured (F2 in FIG. 1) flowing through the sensor flow path S deprives the heat from the temperature sensor hot wire 18 and the flow velocity sensor hot wire 19 bridged in the sensor flow path S. Then, while the electric circuit provided on the back surface side of the sensor substrate 21 detects the outputs of the temperature sensor hot wire 18 and the flow velocity sensor hot wire 19, the temperature sensor hot wire 18 and the flow velocity sensor hot wire 19 are constant. Control the temperature difference.
[0052]
An example of the output at this time is shown in FIGS. The graph of FIG. 12 shows the output (bridge output) from the thermal flow meter 1. The graph of FIG. 13 shows the output (amplifier output) after passing the output from the thermal flow meter 1 through an electrical filter (low-pass filter). 12 and 13 both show the output when the flow rate of the fluid to be measured (F in FIG. 1) flowing into the inlet port 42 of the thermal flow meter 1 is 10 (l / min). Moreover, a continuous line shows the output of the thermal type flow meter 1 which concerns on 1st Embodiment, and a broken line shows the output of the thermal type flow meter before improvement.
[0053]
As is apparent from FIGS. 12 and 13, the thermal flow meter 1 according to the first embodiment has a higher output than the thermal flow meter before improvement (the one of Japanese Patent Application No. 2000-368801, the same applies hereinafter). It can be seen that the vibration width is small. Here, if the ratio of the vibration width to the output value is defined as noise, the noise in the thermal flow meter before improvement is “22.36 (% FS)” in FIG. The noise in the thermal flow meter 1 according to the form is “2.77 (% FS)”. In FIG. 13, the noise in the thermal flow meter before improvement is “4.96 (% FS)”, whereas the noise in the thermal flow meter 1 according to the first embodiment is “0. 43 (% FS) ". That is, according to the thermal flow meter 1 according to the first embodiment, the noise can be reduced to about 1/10. This is because the flow of the fluid to be measured flowing through the sensor flow path S is very well-prepared as described above. The bridge span is “0.415 (V)” for the thermal flow meter 1 according to the first embodiment, and “0.405 (V)” for the thermal flow meter before improvement.
[0054]
Thus, the thermal flow meter 1 has a very stable measurement output. The response is also about 50 msec, which is very sensitive. For this reason, when the thermal flow meter 1 is used for confirmation of adsorption of vacuum adsorption in handling during semiconductor chip mounting, the adsorption state can be accurately determined. This is because the flow rate in the orifice during adsorption and non-adsorption can be measured accurately and stably instantaneously. Therefore, by using the thermal flow meter 1 for the adsorption confirmation, it is possible to accurately confirm the adsorption without erroneously determining that it is not adsorbed although it is actually adsorbed. Thereby, in recent years, the handling operation at the time of mounting of a semiconductor chip (for example, 0.5 mm square) whose size has been reduced can be performed very efficiently.
[0055]
As described above, according to the thermal flow meter 1 according to the first embodiment, the multilayer filter 50 is mounted in the flow path space 44 formed in the body 41. The multilayer filter 50 includes a three-layer mesh portion 51M disposed between the main channel M and the sensor channel S. For this reason, the fluid to be measured flows into the sensor flow path S after passing through the three-layer mesh portion 51M. Thereby, the flow of the fluid to be measured flowing into the sensor flow path S is adjusted. That is, assuming that the flow of the fluid to be measured flowing into the main channel M is disturbed, the three-layer mesh portion 51M provided between the main channel M and the sensor channel S causes the fluid to be measured to flow into the sensor channel S. The flow is trimmed. Moreover, since the mesh part 51M is provided in three layers, a larger rectification effect can be obtained.
[0056]
In addition, the multilayer filter 50 includes a shielding wall 47 formed by the shielding portions 51C, 52C, 53C, and 54C provided on the thin plates 51, 52, 53, and 54 constituting the multilayer filter 50. For this reason, the fluid to be measured flowing out from the sensor flow path S and the fluid to be measured flowing out from the main flow path M merge at the outlet flow path 45 (elbow part 45A) formed in the body 41. That is, the fluid to be measured flowing out from the sensor flow path S and the fluid to be measured flowing out from the main flow path M do not merge near the outlet of the sensor flow path S. Thereby, the junction point of the sensor flow path S and the main flow path M is kept away from the measurement chip 11. Therefore, the vortex of the flow generated at the junction of the sensor flow path S and the main flow path M does not disturb the flow of the fluid to be measured in the sensor flow path S.
[0057]
As described above, in the thermal flow meter 1, the flow of the fluid to be measured in the sensor flow path S is increased even if the measurement flow rate is increased by mounting the multilayer filter 50 in the flow path space 44 formed in the body 41. Is not disturbed. Therefore, a stable measurement output can be obtained even when the measurement flow rate is large.
[0058]
(Second Embodiment)
Next, a second embodiment will be described. Accordingly, FIG. 14 shows a schematic configuration of the thermal flow meter according to the second embodiment. As shown in FIG. 14, the thermal flow meter 201 according to the second embodiment has substantially the same configuration as the thermal flow meter 1 according to the first embodiment. 44 differs in that a multilayer filter 50A is mounted instead of the multilayer filter 50. That is, in the thermal flow meter 201 according to the present embodiment, a multilayer filter 50 </ b> A having a smaller interval between the mesh portions 51 </ b> M than the multilayer filter 50 is mounted in the flow path space 44. For this reason, it demonstrates centering on a different point from 1st Embodiment. In addition, about the thing of the structure similar to 1st Embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted.
[0059]
Therefore, the multilayer filter 50A will be described with reference to FIG. As shown in FIG. 15, the multilayer filter 50 </ b> A is obtained by laminating a total of 11 sheets of four types of thin plates. That is, in order from the bottom, the mesh plate 51, the first shielding plates 52, 52, 52, 52, the second shielding plates 53, 53, the mesh plates 51, 51, 51, and the third shielding plate 54 are laminated and bonded. It is a thing. That is, the multilayer filter 50A is obtained by changing the arrangement of the mesh plate 51 and the second shielding plate 53 in the multilayer filter 50 (see FIG. 4). Due to this change in arrangement, the interval between the mesh portions 51M is 0.2 mm.
[0060]
Then, when the output under the same conditions (flow rate: 10 (l / min)) as in the first embodiment was confirmed with the thermal flow meter 201 having the above configuration, the noise at the bridge output was “4.23. (% FS) ”and the noise at the amplifier output was“ 0.69 (% FS) ”. The bridge span is “0.426 (V)”. The noise at the bridge output of the thermal flow meter before improvement is “22.36 (% FS)”, and the noise at the amplifier output is “4.96 (% FS)”.
[0061]
Therefore, according to the thermal type flow meter 201 according to the second embodiment, the noise can be reduced to about 1/5. That is, the measurement output is stabilized. However, it can be seen that the noise is worse than that of the thermal flow meter 1 according to the first embodiment. From this, it can be said that the mesh portion 51M is more effective when arranged with an interval of about 0.7 mm.
[0062]
As described above in detail, according to the thermal flow meter 201 according to the second embodiment, the multilayer filter 50 </ b> A is mounted in the flow path space 44 formed in the body 41. The multilayer filter 50A is provided with a three-layer mesh portion 51M disposed between the main flow path M and the sensor flow path S. For this reason, the fluid to be measured flows into the sensor flow path S after passing through the three-layer mesh portion 51M. Thereby, the flow of the fluid to be measured flowing into the sensor flow path S is adjusted. That is, assuming that the flow of the fluid to be measured flowing into the main channel M is disturbed, the three-layer mesh portion 51M provided between the main channel M and the sensor channel S causes the fluid to be measured to flow into the sensor channel S. The flow is trimmed. Moreover, since the mesh part 51M is provided in three layers, a larger rectification effect can be obtained.
[0063]
The multilayer filter 50A includes a shielding wall 47 formed by shielding portions 51C, 52C, 53C, and 54C provided on the thin plates 51, 52, 53, and 54 that constitute the multilayer filter 50. For this reason, the fluid to be measured flowing out from the sensor flow path S and the fluid to be measured flowing out from the main flow path M merge at the outlet flow path 45 (elbow part 45A) formed in the body 41. That is, the fluid to be measured flowing out from the sensor flow path S and the fluid to be measured flowing out from the main flow path M do not merge near the outlet of the sensor flow path S. Thereby, the junction point of the sensor flow path S and the main flow path M is kept away from the measurement chip 11. Therefore, the vortex of the flow generated at the junction of the sensor flow path S and the main flow path M does not disturb the flow of the fluid to be measured in the sensor flow path S.
[0064]
As described above, the thermal flow meter 201 has the laminated filter 50A mounted in the flow path space 44 formed in the body 41, so that the flow of the fluid to be measured in the sensor flow path S is increased even when the measurement flow rate increases. Is not disturbed. Therefore, a stable measurement output can be obtained even when the measurement flow rate is large.
[0065]
(Third embodiment)
Next, a third embodiment will be described. Accordingly, FIG. 16 shows a schematic configuration of the thermal type flow meter according to the third embodiment. As shown in FIG. 16, the thermal flow meter 301 according to the third embodiment has substantially the same configuration as that of the thermal flow meter 1 according to the first embodiment. 44 differs in that a multilayer filter 60 is mounted instead of the multilayer filter 50. That is, in the thermal flow meter 301 according to the present embodiment, the multilayer filter 60 having a plurality of grooves is mounted in the flow path space 44. The multilayer filter 60 is also different from the multilayer filter 50 of the first embodiment in that the mesh portion 51M is not provided. For this reason, it demonstrates centering on a different point from 1st Embodiment. In addition, about the thing of the structure similar to 1st Embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted.
[0066]
Therefore, the multilayer filter 60 will be described with reference to FIG. As shown in FIG. 17, the multilayer filter 60 is obtained by laminating a total of ten types of thin plates. That is, the mesh plate 51, the first groove filters 55, 55, 55, 55, 55, 55, 55, 55 and the third shielding plate 54 are laminated and bonded in order from the bottom.
[0067]
Here, the first groove filter 55 will be described with reference to FIG. 18 (a) is a plan view of the first groove filter, FIG. 18 (b) is a cross-sectional view taken along the line AA in FIG. 18 (a), and FIG. 18 (c) is in FIG. 18 (a). It is BB sectional drawing. As shown in FIG. 18, the first groove filter 55 is etched so as to leave the outer peripheral portion 55B, the shielding portion 55C, and the central portion 55D, and to form a groove 55E in the central portion 55D. That is, the first groove filter 55 is provided with a groove 55E in the central portion 53D (see FIG. 8) of the second shielding plate 53. In the central portion 55D of the first groove filter 55, a total of four grooves 55E are formed on each side. The depth of the groove 55E is 0.35 mm, and the width of the groove 55E is 0.9 mm. The interval between adjacent grooves is 1.05 mm. Note that the thickness of the first groove filter 55 is 0.5 mm.
[0068]
By attaching the laminated filter 60 in which the mesh plate 51, the first groove filter 55, and the third shielding plate 54 are laminated and bonded as shown in FIG. 17 to the flow path space 44 formed in the body 41, As shown in FIG. 16, a large number of fine channels are formed in the main channel M by the grooves 55 </ b> E formed in the central portion 55 </ b> D of the first groove filter 55. As a result, the fluid to be measured flowing into the main flow path M flows through each groove 55E. For this reason, the flow of the fluid to be measured flowing through the main flow path M is adjusted. Moreover, in the 1st groove filter 55, by forming the groove | channel 55E in both surfaces, the multilayer filter 60 can be provided with many groove | channels 55E, and a bigger rectification effect is acquired.
[0069]
The multilayer filter 60 includes a shielding wall 47A formed by shielding portions 51C, 54C, 55 provided on the thin plates 51, 54, 55. This shielding plate 47A also has the same effect as the shielding plate 47 provided in the thermal flow meter 1 according to the first embodiment. That is, the vortex of the flow generated at the junction of the sensor flow path S and the main flow path M does not disturb the flow of the fluid to be measured in the sensor flow path S.
[0070]
Then, when the output under the same conditions (flow rate: 10 (l / min)) as in the first embodiment was confirmed with the thermal flow meter 301 having the above configuration, the noise at the bridge output was “6.84. (% FS) ”, and the noise at the amplifier output was“ 1.42 (% FS) ”. The bridge span is “0.679 (V)”. The noise at the bridge output of the thermal flow meter before improvement is “22.36 (% FS)”, and the noise at the amplifier output is “4.96 (% FS)”.
[0071]
Therefore, according to the thermal type flow meter 301 concerning 3rd Embodiment, a noise can be made into about 1/3. That is, the measurement output is stabilized. However, it can be seen that the noise is worse than that of the thermal flow meter 1 according to the first embodiment. From this, it can be said that providing the mesh portion 51M between the main flow path M and the sensor flow path S provides a greater effect than providing the rectification mechanism (groove 55E) in the main flow path M.
[0072]
As described above, according to the thermal type flow meter 301 according to the third embodiment, the multilayer filter 60 is mounted in the flow path space 44 formed in the body 41. The multilayer filter 60 includes a groove 55E that divides the main channel M into a plurality of channels. For this reason, the flow of the fluid to be measured flowing into the main flow path M is adjusted. Thereby, the flow of the fluid to be measured in the main channel M does not adversely affect the flow of the fluid to be measured in the sensor channel S. That is, the flow of the fluid to be measured in the sensor flow path S is always stable.
[0073]
In addition, the multilayer filter 60 includes a shielding wall 47A formed by the shielding portions 51C, 54C, and 55C provided on the thin plates 51, 54, and 55 constituting the multilayer filter 60. For this reason, the fluid to be measured flowing out from the sensor flow path S and the fluid to be measured flowing out from the main flow path M merge at the outlet flow path 45 (elbow part 45A) formed in the body 41. That is, the fluid to be measured flowing out from the sensor flow path S and the fluid to be measured flowing out from the main flow path M do not merge near the outlet of the sensor flow path S. Thereby, the junction point of the sensor flow path S and the main flow path M is kept away from the measurement chip 11. Therefore, the vortex of the flow generated at the junction of the sensor flow path S and the main flow path M does not disturb the flow of the fluid to be measured in the sensor flow path S.
[0074]
As described above, the thermal flow meter 301 has a plurality of grooves 55E (rectifying mechanism) that divides the main channel M into a plurality of channels by mounting the multilayer filter 60 in the channel space 44 formed in the body 41. ) Is arranged, the flow of the fluid to be measured flowing through the main flow path M is adjusted. Further, a shielding plate 47A that moves away from the measuring chip 11 at a confluence point of the sensor flow path S and the main flow path M to such an extent that the vortex of the flow generated at the confluence point does not disturb the flow of the fluid to be measured in the sensor flow path S. Be placed. Accordingly, the flow of the fluid to be measured in the main flow path M is not disturbed, and the flow vortex generated at the junction of the sensor flow path S and the main flow path M does not disturb the flow of the fluid to be measured in the sensor flow path S. For this reason, even when the measurement flow rate is large, the flow of the fluid to be measured in the sensor flow path S is not disturbed. Therefore, a stable measurement output can be obtained even when the measurement flow rate is large.
[0075]
(Fourth embodiment)
Finally, a fourth embodiment will be described. Accordingly, FIG. 19 shows a schematic configuration of the thermal type flow meter according to the fourth embodiment. As shown in FIG. 19, the thermal flow meter 401 according to the fourth embodiment has substantially the same configuration as that of the thermal flow meter 1 according to the first embodiment. 44 differs in that a multilayer filter 70 is mounted instead of the multilayer filter 50. That is, in the thermal flow meter 401 according to the present embodiment, the multilayer filter 70 having a plurality of grooves is mounted in the flow path space 44 as in the third embodiment. However, the multilayer filter 70 is different from the multilayer filter 60 of the third embodiment in that the shielding wall 47A is not provided and the number of grooves is different. For this reason, it demonstrates centering on a different point from 1st (and 3rd) embodiment. In addition, about the thing of the structure similar to 1st Embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted.
[0076]
Therefore, the multilayer filter 70 will be described with reference to FIG. As shown in FIG. 20, the multilayer filter 70 is obtained by laminating a total of ten kinds of two kinds of thin plates. That is, the mesh plate 51 and the second groove filters 56, 56, 56, 56, 56, 56, 56, 56, 56 are laminated and bonded in order from the bottom.
[0077]
Here, the second groove filter 56 will be described with reference to FIG. 21 (a) is a plan view of the second groove filter, FIG. 21 (b) is a cross-sectional view taken along line AA in FIG. 21 (a), and FIG. 21 (c) is in FIG. 21 (a). It is BB sectional drawing. As shown in FIG. 21, the second groove filter 56 is etched so that a groove 56E is formed in the central portion 56D while leaving the outer peripheral portion 56B and the central portion 56D. That is, in the second groove filter 56, the groove 56E is provided in the central portion 53D (see FIG. 8) of the second shielding plate 53, but the shielding portion 53C is not provided. The central portion 56D has three grooves 56E formed on one side. The depth of the groove 56E is 0.35 mm, and the width of the groove 55E is 1.1 mm. The interval between adjacent grooves is 0.2 mm. The thickness of the second groove filter 56 is 0.5 mm.
[0078]
By attaching the laminated filter 70 in which the mesh plate 51 and the second groove filter 55 are laminated and bonded as shown in FIG. 20 to the flow path space 44 formed in the body 41, as shown in FIG. A large number of fine flow paths are formed in the main flow path M by the grooves 56E formed in the central portion 56D of the two-groove filter 56. Thereby, the fluid to be measured flowing into the main flow path M flows through each groove 56E. For this reason, the flow of the fluid to be measured flowing through the main flow path M is adjusted. Further, since the three grooves 56E are formed in the second groove filter 56, the multilayer filter 70 can be provided with more grooves 56E, and a larger rectification effect can be obtained.
[0079]
Then, when the output under the same conditions (flow rate: 10 (l / min)) as in the first embodiment was confirmed with the thermal flow meter 401 having the above configuration, the noise at the bridge output was “13.47. (% FS) ”, and the noise at the amplifier output was“ 1.76 (% FS) ”. The bridge span is “0.498 (V)”. The noise at the bridge output of the thermal flow meter before improvement is “22.36 (% FS)”, and the noise at the amplifier output is “4.96 (% FS)”.
[0080]
Therefore, according to the thermal type flow meter 401 which concerns on 4th Embodiment, a noise can be made into about 3/5. That is, the measurement output is stabilized. However, it can be seen that the noise is worse than that of the thermal flow meter 1 according to the third embodiment. From this, it can be said that a larger effect can be obtained by providing the shielding wall 47A.
[0081]
Further, instead of mounting the multilayer filter 70 in the flow path space 44 of the body 41, a cylindrical pin 80 having a plurality of fins 81 as shown in FIG. This is because providing such a pin 80 in the main channel M also forms a plurality of channels in the main channel M, and the flow of the fluid to be measured flowing through the main channel M is adjusted.
[0082]
And when this pin 80 is arranged in the main flow path M and the thermal flow meter is used to confirm the output under the same conditions (flow rate: 10 (l / min)) as in the first embodiment, the bridge output The noise at was 16.2 (% FS), and the noise at the amplifier output was 3.26 (% FS). The bridge span is “0.469 (V)”. The noise at the bridge output of the thermal flow meter before improvement is “22.36 (% FS)”, and the noise at the amplifier output is “4.96 (% FS)”. Therefore, the noise can be reduced to about 3/4 only by arranging the pin 80 in the main flow path M. That is, the measurement output is stabilized. However, the stabilizing effect is not so great.
[0083]
As described above, according to the thermal flow meter 401 according to the fourth embodiment, the multilayer filter 70 is mounted in the flow path space 44 formed in the body 41. The multilayer filter 70 includes a groove 56E that divides the main channel M into a plurality of channels. For this reason, the flow of the fluid to be measured flowing into the main flow path M is adjusted. Thereby, the flow of the fluid to be measured in the main channel M does not adversely affect the flow of the fluid to be measured in the sensor channel S. That is, the flow of the fluid to be measured in the sensor flow path S is stable even when the measurement flow rate is increased. Therefore, a stable measurement output can be obtained even when the measurement flow rate is large.
[0084]
It should be noted that the above-described embodiment is merely an example and does not limit the present invention in any way, and various improvements and modifications can be made without departing from the scope of the invention. For example, in the above-described embodiment, four types of multilayer filters are exemplified, but the present invention is not limited to this, and the multilayer filters can be configured by arbitrarily combining the thin plates 51 to 56.
[0085]
【The invention's effect】
As described above, according to the thermal type flow meter according to the present invention, by providing a filter between the bypass flow channel and the sensor flow channel, the measured flow rate increases and the flow of fluid in the bypass flow channel is disturbed. However, the flow of the fluid flowing into the sensor flow path is adjusted. In addition, since the fluid flow is adjusted by forming a plurality of flow paths in the bypass flow path, the flow of the fluid in the bypass flow path is adjusted even if the measured flow rate is increased. Furthermore, since it has the shielding wall which joins the fluid which flows out from a sensor flow path, and the fluid which flows out from a bypass flow path in the exit flow path formed in the body, the confluence | merging point of a sensor flow path and a bypass flow path is set. Can be kept away from heat rays. As a result, the flow of fluid in the sensor flow path is stable even when the measured flow rate is increased. Therefore, the measurement output can be stably obtained even if the measurement flow rate is increased.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of a thermal type flow meter according to a first embodiment.
FIG. 2 is a plan view of the body.
3 is a cross-sectional view taken along the line AA in FIG.
FIG. 4 is an exploded perspective view of a multilayer filter.
5A and 5B are diagrams showing a mesh plate, where FIG. 5A is a plan view and FIG. 5B is a cross-sectional view taken along line AA.
6 is an enlarged view of the mesh portion of FIG. 5. FIG.
7A and 7B are views showing a first shielding plate, in which FIG. 7A is a plan view and FIG. 7B is a cross-sectional view taken along line AA.
8A and 8B are diagrams showing a second shielding plate, in which FIG. 8A is a plan view and FIG. 8B is a cross-sectional view taken along line AA.
9A and 9B are views showing a third shielding plate, in which FIG. 9A is a plan view and FIG. 9B is a cross-sectional view taken along line AA.
FIG. 10 is a perspective view of a sensor substrate.
11A and 11B are diagrams showing a measurement chip, in which FIG. 11A is a plan view and FIG. 11B is a side view.
FIG. 12 is a diagram showing an example of an output (bridge output) of a thermal flow meter.
FIG. 13 is a diagram similarly showing an example of an output (amplifier output) of a thermal flow meter.
FIG. 14 is a schematic configuration diagram of a thermal flow meter according to a second embodiment.
FIG. 15 is an exploded perspective view of a multilayer filter.
FIG. 16 is a schematic configuration diagram of a thermal type flow meter according to a third embodiment.
FIG. 17 is an exploded perspective view of a multilayer filter.
18A and 18B are views showing a first groove filter, in which FIG. 18A is a plan view, FIG. 18B is a cross-sectional view along AA, and FIG. 18C is a cross-sectional view along BB.
FIG. 19 is a schematic configuration diagram of a thermal type flow meter according to a fourth embodiment.
FIG. 20 is an exploded perspective view of the multilayer filter.
FIGS. 21A and 21B are views showing a second groove filter, where FIG. 21A is a plan view, FIG. 21B is a cross-sectional view along AA, and FIG. 21C is a cross-sectional view along BB;
FIG. 22 is a front view of a rectifying pin in a thermal flow meter according to a fifth embodiment.
FIG. 23 is a cross-sectional view of a conventional thermal flow meter.
FIG. 24 is a perspective view of a measuring element used in a conventional heat flow meter.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Thermal type flow meter 41 Body 44 Flow path space 47 Shielding wall 50 Multilayer filter 51 Mesh board 51M Mesh part 52 1st shielding board 53 2nd shielding board 54 3rd shielding board 55 1st groove filter 55E Grooves 52C, 53C, 54C , 55C Shielding part 56 Second groove filter 56E Groove M Main flow path (bypass flow path)
S Sensor flow path

Claims (12)

A sensor flow path with a hot wire for measuring the flow rate; and
A bypass flow path for the sensor flow path;
Laminating a thin plate having an opening, and having a laminate that divides the fluid into the sensor flow path and the bypass flow path therein,
A thermal flowmeter characterized by performing suction confirmation at the suction nozzle by detecting the flow rate of the fluid flowing through the suction nozzle . In the thermal type flow meter according to claim 1,
  The laminated body includes a thin plate having different areas of the openings. In the thermal type flow meter according to claim 1,
The laminated body includes a thin plate in which the opening is a mesh . In the thermal type flow meter according to claim 3,
The thin plate whose opening is a mesh is laminated through a spacer having a predetermined thickness. In the thermal type flow meter according to any one of claims 1 to 4,
A thermal flow meter comprising a rectifying mechanism that regulates the flow of fluid by forming a plurality of channels in the bypass channel. In the thermal type flow meter according to claim 5,
The thermal flow meter according to claim 1, wherein the rectifying mechanism is a laminate of thin plates having grooves. In the thermal type flow meter according to claim 6,
A thermal flow meter, wherein a plurality of grooves are formed in the thin plate. In the thermal type flow meter according to claim 5,
The rectifying mechanism is a pin formed with a plurality of fins. A sensor flow path with a hot wire for measuring the flow rate; and
A bypass flow path for the sensor flow path;
It is formed by laminating a plurality of shielding plates, and has a shielding wall that joins the fluid flowing out from the sensor flow path and the fluid flowing out from the bypass flow path in an outlet flow path ,
A thermal flowmeter characterized by performing suction confirmation at the suction nozzle by detecting the flow rate of the fluid flowing through the suction nozzle . In the thermal type flow meter according to any one of claims 1 to 9,
The bypass channel is a substrate provided with an electrode for an electric circuit connected to an electric circuit for performing a measurement principle using a heat ray on the surface, and a body having a fluid channel including a side opening, Formed by close contact so as to close the side opening,
The sensor flow path is formed by mounting a measurement chip provided with a hot wire and a hot wire electrode connected to the hot wire on the substrate by bonding the hot wire electrode and the electric circuit electrode. A thermal flow meter formed by a groove provided in at least one of a chip or the substrate. A substrate having an electrode for an electric circuit connected to an electric circuit for performing a measurement principle using a hot wire on a surface is provided with a fluid channel having a side opening and an outlet flow that is not collinear with the fluid channel. A bypass channel formed by close contact with the body in which the path is formed so as to close the side opening;
A measuring chip provided with a hot wire and a hot wire electrode connected to the hot wire is mounted on the substrate by bonding the hot wire electrode and the electric circuit electrode, so that at least the measuring chip or the substrate is mounted. A sensor flow path formed by a groove provided on one side,
A filter in which a plurality of meshes are laminated between the bypass flow path and the sensor flow path,
A shielding wall that joins the fluid flowing out from the sensor flow path and the fluid flowing out from the bypass flow path in the outlet flow path;
A thermal flowmeter characterized by performing suction confirmation at the suction nozzle by detecting the flow rate of the fluid flowing through the suction nozzle . The thermal flow meter according to claim 11, wherein
The thermal flow meter, wherein the shielding wall is composed of a plurality of shielding plates, and the filter and the shielding wall are provided in one laminate.

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