• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A flow controller for controlling a flow rate of a fluid flowing through a fluid passage comprises a control valve for which a degree of opening of a valve is adjusted by a control signal, an orifice arranged on an outflow side of the control valve, a combined sensor arranged on an inflow side of the orifice for almost simultaneously detecting a pressure and a temperature of the fluid, and a control circuit. The combined sensor includes a pressure-detecting element for deriving a detection signal corresponding to the pressure of the fluid, and a temperature-detecting element for deriving a detection signal corresponding to the temperature of the fluid. The pressure-detecting element and the temperature-detecting element are arranged closely to one another on an identical surface of a pressure-receiving section.
    公开号:US20010009163A1
    申请号:US09/764,097
    申请日:2001-01-19
    公开日:2001-07-26
    发明作者:Kenichi Kurosawa
    申请人:SMC Corp;
    IPC主号:G05D7-0635
    专利说明:
    [0001] 1. Field of the Invention [0001]
    [0002] The present invention relates to a combined sensor for almost simultaneously detecting the pressure and the temperature of a fluid, and a flow controller provided with the combined sensor for controlling the flow rate of a fluid flowing through a fluid passage. [0002]
    [0003] 2. Description of the Related Art [0003]
    [0004] It is necessary to accurately control the flow rate of a process fluid to be supplied to a processing equipment, for example, in a dry etching apparatus and a thin film-producing apparatus in the process for producing semiconductors. To control the flow rate of the process fluid, a flow controller is arranged in a fluid passage to supply the process fluid to the processing equipment. [0004]
    [0005] The flow controller comprises a pressure sensor for detecting the pressure of the fluid, a temperature sensor for detecting the temperature, and a control valve for controlling the flow rate. Detection signals detected by the pressure sensor and the temperature sensor are introduced into a control circuit in the flow controller respectively. The flow rate of the fluid is calculated based on the detection signal in the control circuit. Thereafter, the flow rate is controlled by adjusting a degree of opening of the control valve depending upon a control signal transmitted from the control circuit to the control valve. [0005]
    [0006] In the conventional flow controller, the pressure sensor and the temperature sensor are arranged separately one by one, and use mutually different detection positions for detecting the pressure and the temperature of the fluid. For the above reason, the following drawback arises. That is, a large space is required for both of the detection positions, and the flow controller itself tends to have a large size. Consequently, a large space is required for installation of the flow controller. [0006] SUMMARY OF THE INVENTION
    [0007] A general object of the present invention is to provide a combined sensor which can reduce the space of the detection positions and realize the miniaturization by closely arranging on an identical surface the detection positions for outputting detection signals corresponding to the pressure and the temperature of a fluid respectively. [0007]
    [0008] A principal object of the present invention is to provide a flow controller which is provided with a miniaturized combined sensor and which can reduce the installation space. [0008]
    [0009] The above and other objects, features, and advantages of the present invention will become more apparent from the following description when taken in conjunction with the accompanying drawings in which a preferred embodiment of the present invention is shown by way of illustrative example. [0009] BRIEF DESCRIPTION OF THE DRAWINGS
    [0010] FIG. 1 shows a vertical sectional view illustrating an arrangement of a flow controller according to a first embodiment of the present invention; [0010]
    [0011] FIG. 2 shows a block diagram depicting an illustrative arrangement of the flow controller according to the first embodiment; [0011]
    [0012] FIG. 3 shows, with partial omission, a vertical sectional view illustrating a combined sensor provided in the flow controller; [0012]
    [0013] FIG. 4 shows a view as viewed in a direction of the arrow A shown in FIG. 3; [0013]
    [0014] FIG. 5 shows, with partial omission, a vertical sectional view illustrating a combined sensor based on the use of a pressure-receiving section according to a modified embodiment; [0014]
    [0015] FIG. 6 shows a view as viewed in a direction of the arrow B shown in FIG. 5; [0015]
    [0016] FIG. 7 shows a vertical sectional view illustrating an arrangement of a flow controller according to a second embodiment of the present invention; and [0016]
    [0017] FIG. 8 shows a block diagram depicting an illustrative arrangement of the flow controller according to the second embodiment. [0017] DESCRIPTION OF THE PREFERRED EMBODIMENTS
    [0018] A flow controller [0018] 10 according to a first embodiment of the present invention is shown in FIGS. 1 and 2. The flow controller 10 is generally connected to a fluid supply passage (not shown) for a process fluid (for example, air) to be used for an unillustrated apparatus for producing semiconductor parts. The flow controller 10 controls the flow rate of the fluid flowing through the fluid supply passage.
    [0019] The flow controller [0019] 10 comprises a control valve 12, an orifice 16, a combined sensor 14, and a fluid passage 17. The degree of opening of the control valve 12 is adjusted by a control signal. The orifice 16 is arranged on the outflow side of the control valve 12. The combined sensor 14 is arranged on the inflow side of the orifice 16 for detecting the pressure and the temperature of the fluid (F). The fluid passage 17 is provided for the fluid (F).
    [0020] The fluid (F) of which the flow rate is controlled by the flow controller [0020] 10 is a gas. The flow velocity of the fluid (F) passing through the orifice 16 is the sound velocity.
    [0021] The flow controller [0021] 10 has a control circuit 18. The detection signals corresponding to the pressure and the temperature of the fluid (F) sensed by the combined sensor 14 are introduced respectively into the control circuit 18. Further, a control signal for adjusting the degree of the opening of the control valve 12 is transmitted from the control circuit 18 as well.
    [0022] The hole (not shown) formed for allowing the fluid (F) to pass through the orifice [0022] 16 has a cross-sectional area previously set to have a predetermined value used to calculate the flow rate of the fluid (F) as described later on.
    [0023] Next, the arrangement of the combined sensor [0023] 14 will be explained with reference to FIGS. 3 and 4.
    [0024] As shown in FIG. 3, the combined sensor [0024] 14 includes a casing 20, a pressure-receiving section 24, a ring 28, and a base board 30. The casing 20 is made of metal which is formed with a projection 22 connected to the fluid passage 17. The pressure-receiving section 24 is made of stainless steel (for example, SUS316 based on the standard of JIS) fastened in the casing 20 and including a recess having a rectangular vertical cross section. The ring 28 is secured to an upper surface 26 of the casing 20. The base board 30 is made of resin.
    [0025] The pressure-receiving section [0025] 24 has a thin-walled section 32 formed at a substantially central portion, and a thick-walled section 36 formed at the circumferential edge of the thin-walled section 32. The thin-walled section 32 and the thick-walled section 36 are integrally formed. A chamber 38 closed by the pressure-receiving section 24 is formed in the casing 20.
    [0026] The surface of the pressure-receiving section [0026] 24 on the side of the chamber 38 is coated with an insulating layer 39 made of resin. Pressure-detecting elements 40 and a temperature-detecting element 42 are arranged closely to one another on the insulating layer 39. The pressure-detecting elements 40 are secured to the thin-walled section 32 while the temperature-detecting element 42 is secured to the thick-walled section 36. The shapes and other features of the pressure-detecting element 40 and the temperature-detecting element 42 will be described in detail later on. The surface of the pressure-receiving section 24 on the opposite side to the chamber 38 communicates with the fluid passage 17. Hence, the surface of the pressure-receiving section 24 constantly contacts with the fluid (F).
    [0027] A plurality of lead wires [0027] 44 for the pressure-detecting elements 40 and a lead wire 46 for the temperature-detecting element 42 penetrate through holes 48 formed to communicate with the casing 20 and the base plate 30. A plurality of the lead wires 44 and the lead wire 46 are bonded to the base plate 30. The hole 48 has a larger diameter on the side of the casing 20 than that on the side of the base plate 30.
    [0028] The hole [0028] 48 is closed by heat-insulating rubber 50 and glass 52 to insulate the lead wires 44 and the lead wire 46. The heat-insulating rubber 50 and the glass 52 improve the heat-insulating effect of the lead wires 44 and the lead wire 46. The heat-insulating rubber 50 and the glass 52 maintain the air-tightness of the chamber 38 as well. Therefore, the chamber 38 formed by the casing 20 and the pressure-receiving section 24 is kept in vacuum.
    [0029] A plurality of lead wires [0029] 54 connected to the control circuit 18 are bonded to bonding portions of the lead wires 44 and the lead wire 46 on the base plate 30. Accordingly, the detection signals outputted by the pressure-detecting elements 40 and the temperature-detecting element 42 are introduced into the control circuit 18 respectively. To insulate the bonding portions of the lead wires 44 and the lead wire 46, silicone rubber mold which is a heat-insulating material 56 is charged onto the base plate 30 in the ring 28. As a result, the silicone rubber mold is flushed with the ring 28.
    [0030] Explanation will now be made with reference to FIG. 4 for the arrangement and other features of the pressure-detecting element [0030] 40 and the temperature-detecting element 42.
    [0031] The pressure-detecting element [0031] 40 senses the pressure of the fluid (F) to derive the detection signal corresponding to the pressure. As shown in FIG. 4, strain gauges to serve as the pressure-detecting elements 40 are arranged substantially on a straight line at a substantially central portion of the pressure-receiving section 24. The pressure-detecting elements 40 are brazed with solder to the insulating layer 39 formed on the thin-walled section 32 of the pressure-receiving section 24.
    [0032] The temperature-detecting element [0032] 42 senses the temperature of the fluid (F) to derive the detection signal corresponding to the temperature. The temperature-detecting element 42 is made of CrN (chromium nitride) having its resistance value varied depending on the change of the temperature. As shown in FIG. 4, the temperature-detecting element 42 is brazed with solder to the insulating layer 39 formed on the thick-walled section 36 of the pressure-receiving section 24 in the same manner as the pressure-detecting elements 40 described above.
    [0033] The pressure-detecting elements [0033] 40 and the temperature-detecting element 42 are arranged closely to one another without any mutual interference on the insulating layer 39 (see FIG. 4).
    [0034] The flow controller [0034] 10 according to the first embodiment of the present invention is basically constructed as described above. Next, the function and effect of the flow controller 10 will be explained.
    [0035] When, the fluid (F) flows from the control valve [0035] 12 through the combined sensor 14 and the orifice 16, the flow rate of the fluid (F) is controlled. Thereafter, the fluid (F) is introduced into the unillustrated processing equipment. During above process, the detection signals corresponding to the pressure and the temperature are derived by the combined sensor 14 to calculate the flow rate of the fluid (F).
    [0036] As described above, the surface of the thin-walled section [0036] 32 of the pressure-receiving section 24 on the opposite side to the chamber 38 constantly contacts with the fluid (F). Therefore, the surface is pressurized by the fluid (F). Accordingly, the detection signal corresponding to the pressure of the fluid (F) is derived by the pressure-detecting elements 40 secured to the insulating layer 39 on the thin-walled section 32. An error of detecting the amount of strain of the pressure-receiving section 24 corresponding to the pressure of the fluid (F) can be avoided as less as possible because the pressure-detecting elements 40 are secured to the insulating layer 39 on the thin-walled section 32.
    [0037] The temperature-detecting element [0037] 42 is secured to the thick-walled section 36 of the pressure-receiving section 24. The temperature of the fluid (F) is transmitted to the pressure-receiving section 24, and the resistance value of the temperature-detecting element 42 is changed. Thus, the detection signal corresponding to the temperature of the fluid (F) is sensed. The temperature-detecting element 42 is prevented from undergoing any mechanical strain caused by any factor other than the temperature of the fluid (F) by securing the temperature-detecting element 42 to the thick-walled section 36.
    [0038] The detection signals corresponding to the detected pressure and the detected temperature of the fluid (F) are introduced into the control circuit [0038] 18 respectively. The flow rate of the fluid (F) is calculated by the control circuit 18 based on the introduced detection signals corresponding to the pressure and the temperature of the fluid (F). In the first embodiment, the fluid (F) of which the flow rate is controlled by the flow controller 100 is the gas (for example, air). The flow velocity of the fluid (F) passing through the orifice 16 is the sound velocity. Therefore, the flow rate can be calculated by the following expression (1).Q = 1.85  S · P H  273 T( 1 )
    [0039] In the expression (1), Q represents the volume flow rate (1/second), S represents the cross-sectional area (mm[0039] 2) of the unillustrated hole formed for the orifice 16, PH represents the fluid pressure (MPa abs), and T represents the temperature (K) of the fluid.
    [0040] If the calculated flow rate is not a predetermined one, the control signal for adjusting the degree of the opening of the control valve [0040] 12 is transmitted from the control circuit 18 to the control valve 12. Accordingly, since the degree of the opening of the control valve 12 is adjusted, the fluid (F) can be allowed to flow at a predetermined flow rate.
    [0041] Instead of the pressure-receiving section [0041] 24 used for the flow controller 10 according to the first embodiment, it is also preferable to use a pressure-receiving section 80 as shown in a modified embodiment in FIG. 5. The pressure-receiving section 80 has a thin-walled section 82 having an annular configuration. Further, the pressure-receiving section 80 has a first thick-walled section 84 and a second thick-walled section 86 having mutually different thickness. The first thick-walled section 84 is provided at the circumferential edge of the thin-walled section The second thick-walled section 86 is provided on the surface at a substantially central portion of the thin-walled section 82 for the purpose of contacting with the fluid (F). The thin-walled section 82 and the first and second thick-walled sections 84, 86 are integrally formed.
    [0042] The surface of the pressure-receiving section [0042] 80 on the side of the chamber 38 is coated with the insulating layer 39. The temperature-detecting element 42 is brazed to the insulating layer 39 formed on the second thick-walled section 86. Therefore, the temperature-detecting element 42 can be prevented from undergoing any mechanical strain caused by any factor other than the temperature of the fluid (F).
    [0043] The temperature-detecting element [0043] 42 is arranged at the substantially central portion corresponding to the second thick-walled section 86. A plurality of the pressure-detecting elements 40 is arranged substantially on the straight line with the temperature-detecting element 42 intervening therebetween. The temperature-detecting element 42 and a plurality of the pressure-detecting element are arranged closely to one another on the identical plane without any mutual interference (see FIG. 6).
    [0044] Additionally, the pressure-receiving section [0044] 80 can be used for a flow controller 100 according to a second embodiment described below.
    [0045] Next, the flow controller [0045] 100 according to the second embodiment will be explained with reference to FIGS. 7 and 8. As for the flow controller 100 according to the second embodiment, the same constitutive components as those of the flow controller 10 according to the first embodiment described above are designated by the same reference numerals, and the detailed explanation thereof will be omitted.
    [0046] The flow controller [0046] 100 according to the second embodiment is constructed in almost the same manner as the flow controller 10 according to the first embodiment. However, the arrangement of combined sensors 14 and the number of arranged combined sensors 14 are different.
    [0047] As shown in FIGS. 7 and 8, the flow controller [0047] 100 according to the second embodiment comprises the combined sensors 14 for detecting the pressure and the temperature of the fluid (F). The combined sensors 14 are arranged on the inflow and the outflow sides of the orifice 16. The fluid (F) of which the flow rate is controlled by the flow controller 100 is the gas. The flow velocity of the fluid (F) passing through the orifice 16 is subsonic (less than the sound velocity).
    [0048] The function and effect of the flow controller [0048] 100 according to the second embodiment are almost the same as the function and effect of the flow controller 10 according to the first embodiment described above.
    [0049] However, in the second embodiment, the fluid (F) of which the flow rate is controlled by the flow controller [0049] 100 is the gas (for example, air). The flow velocity of the fluid (F) passing through the orifice 16 is subsonic (less than the sound velocity). Therefore, when the flow rate is calculated by the control circuit 18, the flow rate is expressed by the following expression (2).Q = 3.77  S P L  ( P H - P L ) 273 T( 2 )
    [0050] In the expression (2), Q represents the volume flow rate (1/second), S represents the cross-sectional area (mm[0050] 2) of the unillustrated hole formed for the orifice 16, PH represents the fluid pressure (MPa abs) on the inflow side of the orifice 16, PL represents the fluid pressure (MPa abs) on the outflow side of the orifice 16, and T represents the temperature (K) of the fluid on the outflow side of the orifice 16.
    [0051] It is a matter of course that the combined sensor and the flow controller provided with the combined sensor according to the present invention are not limited to the embodiments described above, which may be embodies in other various forms without deviating from the gist or essential characteristics of the present invention. [0051]
    权利要求:
    Claims (11)
    [1" id="US-20010009163-A1-CLM-00001] 1. A combined sensor comprising, in a casing, a pressure-receiving section for receiving a pressure of a fluid, a pressure-detecting element for sensing said pressure of said fluid to derive a detection signal corresponding to said pressure, and a temperature-detecting element for sensing a temperature of said fluid to derive a detection signal corresponding to said temperature, wherein:
    said pressure-detecting element and said temperature-detecting element are arranged closely to one another on an identical surface of said pressure-receiving section.
    [2" id="US-20010009163-A1-CLM-00002] 2. The combined sensor according to
    claim 1 , wherein:
    said pressure-receiving section has a thin-walled section and a thick-walled section; and
    said thin-walled section and said thick-walled section are integrally formed.
    [3" id="US-20010009163-A1-CLM-00003] 3. The combined sensor according to
    claim 2 , wherein said pressure-detecting element is secured to said thin-walled section, while said temperature-detecting element is secured to said thick-walled section.
    [4" id="US-20010009163-A1-CLM-00004] 4. A flow controller provided with a combined sensor, for controlling a flow rate of a fluid flowing through a fluid passage, said flow controller comprising:
    a control valve for controlling said flow rate of said fluid, a throttle arranged on an outflow side of said control valve, said combined sensor arranged on an inflow side of said throttle for almost simultaneously detecting a pressure and a temperature of said fluid, and a control circuit, wherein:
    detection signals corresponding to said pressure and said temperature of said fluid sensed by said combined sensor are introduced into said control circuit respectively, and a control signal for adjusting a degree of opening of said control valve is derived from said control circuit to said control valve.
    [5" id="US-20010009163-A1-CLM-00005] 5. The flow controller provided with said combined sensor according to
    claim 4 , wherein:
    said combined sensor comprises, in a casing, a pressure-receiving section for receiving said pressure of said fluid, a pressure-detecting element for sensing said pressure of said fluid to derive said detection signal corresponding to said pressure, and a temperature-detecting element for sensing said temperature of said fluid to derive said detection signal corresponding to said temperature, wherein:
    said pressure-detecting element and said temperature-detecting element are arranged closely to one another on an identical surface of said pressure-receiving section.
    [6" id="US-20010009163-A1-CLM-00006] 6. The flow controller provided with said combined sensor according to
    claim 5 , wherein:
    said pressure-receiving section has a thin-walled section and a thick-walled section; and
    said thin-walled section and said thick-walled section are integrally formed.
    [7" id="US-20010009163-A1-CLM-00007] 7. The flow controller provided with said combined sensor according to
    claim 6 , wherein said pressure-detecting element is secured to said thin-walled section, while said temperature-detecting element is secured to said thick-walled section.
    [8" id="US-20010009163-A1-CLM-00008] 8. A flow controller provided with combined sensors, for controlling a flow rate of a fluid flowing through a fluid passage, said flow controller comprising:
    a control valve for controlling said flow rate of said fluid, a throttle arranged on an outflow side of said control valve, a pair of said combined sensors arranged on inflow and outflow sides of said throttle respectively for almost simultaneously detecting a pressure and a temperature of said fluid, and a control circuit, wherein:
    detection signals corresponding to said pressure and said temperature of said fluid sensed by said combined sensors are introduced into said control circuit respectively, and a control signal for adjusting a degree of said opening of said control valve is derived from said control circuit to said control valve.
    [9" id="US-20010009163-A1-CLM-00009] 9. The flow controller provided with said combined sensors according to
    claim 8 , wherein:
    said combined sensor comprises, in a casing, a pressure-receiving section for receiving said pressure of said fluid, a pressure-detecting element for sensing said pressure of said fluid to derive said detection signal corresponding to said pressure, and a temperature-detecting element for sensing said temperature of said fluid to derive said detection signal corresponding to said temperature, wherein:
    said pressure-detecting element and said temperature-detecting element are arranged closely to one another on an identical surface of said pressure-receiving section.
    [10" id="US-20010009163-A1-CLM-00010] 10. The flow controller provided with said combined sensors according to
    claim 9 , wherein:
    said pressure-receiving section has a thin-walled section and a thick-walled section; and
    said thin-walled section and said thick-walled section are integrally formed.
    [11" id="US-20010009163-A1-CLM-00011] 11. The flow controller provided with said combined sensors according to
    claim 10 , wherein said pressure-detecting element is secured to said thin-walled section, while said temperature-detecting element is secured to said thick-walled section.
    类似技术:
    公开号 | 公开日 | 专利标题
    US6561216B2|2003-05-13|Combined sensor and flow controller provided with combined sensor
    JP4298476B2|2009-07-22|Fluid control device
    JP2837112B2|1998-12-14|Mass flow control method and apparatus using sonic nozzle
    US6901794B2|2005-06-07|Multiple technology flow sensor
    US5950923A|1999-09-14|Suck back valve
    US7270011B2|2007-09-18|Combined absolute-pressure and relative-pressure sensor
    KR20030090485A|2003-11-28|Chemically inert flow control with non-contaminating body
    US7062974B2|2006-06-20|Pressure transmitter
    JP2005241279A|2005-09-08|Sensor made of anti-corrosion metal for fluid and fluid supply apparatus
    WO1999063412A1|1999-12-09|Gas supply equipment with pressure type flow rate control device
    WO2004092688A1|2004-10-28|Thermal type mass flow rate sensor made of corrosion resistant metal, and fluid supply equipment using the same
    US6732589B2|2004-05-11|Pressure sensor, a method for manufacturing a pressure sensor and a combustion engine having a pressure sensor
    US5515735A|1996-05-14|Micromachined flow sensor device using a pressure difference and method of manufacturing the same
    US5988210A|1999-11-23|Flow control valve utilizing sonic nozzle
    US8485041B2|2013-07-16|Sensor system, method for operating a sensor system, and method for manufacturing a sensor system
    US6041659A|2000-03-28|Methods and apparatus for sensing differential and gauge static pressure in a fluid flow line
    US6539813B1|2003-04-01|Throttle structure and flow meter incorporated with throttle structure
    US20070000332A1|2007-01-04|Pressure transmitter
    EP1790964B1|2017-08-23|A sensor arrangement for measuring a pressure and a temperature in a fluid
    JP2002156302A|2002-05-31|Pressure sensor
    US5948992A|1999-09-07|Semiconductor pressure detecting device
    US8479580B2|2013-07-09|Pressure transducer arrangement
    US6626044B1|2003-09-30|Freeze resistant sensor
    JPH07151326A|1995-06-13|Combustion device
    JPH07167724A|1995-07-04|Method and apparatus for detecting pressure
    同族专利:
    公开号 | 公开日
    US6561216B2|2003-05-13|
    JP2001201414A|2001-07-27|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    EP1475684A1|2001-12-28|2004-11-10|Fujikin Incorporated|Advanced pressure type flow control device|
    US20040247446A1|2001-10-03|2004-12-09|Berryman Walter Henry|Pump control system|
    DE102008018089A1|2008-04-09|2009-10-15|Endress & Hauser Meßtechnik GmbH & Co. KG|Method for filling i.e. oil, from tank in bottle, involves adjusting flow rate of medium via throttle in dependent of measured temperature of medium, and adjusting filling pressure in dependent of measured temperature|
    CN102829828A|2011-06-17|2012-12-19|株式会社堀场Stec|Flow rate measuring device and flow rate controller|JP2544435B2|1988-04-06|1996-10-16|株式会社日立製作所|Multi-function sensor|
    JPH0318735A|1989-06-15|1991-01-28|Matsushita Electric Ind Co Ltd|Pressure and temperature sensor element|
    US5259248A|1990-03-19|1993-11-09|Hitachi Ltd.|Integrated multisensor and static and differential pressure transmitter and plant system using the integrated multisensor|
    FR2661558B1|1990-04-27|1992-07-31|Schlumberger Ind Sa|HYDROSTATIC PRESSURE TRANSDUCER.|
    JP3182807B2|1991-09-20|2001-07-03|株式会社日立製作所|Multifunctional fluid measurement transmission device and fluid volume measurement control system using the same|
    US5463904A|1994-02-04|1995-11-07|The Foxboro Company|Multimeasurement vortex sensor for a vortex-generating plate|
    JP3291161B2|1995-06-12|2002-06-10|株式会社フジキン|Pressure type flow controller|
    US5868159A|1996-07-12|1999-02-09|Mks Instruments, Inc.|Pressure-based mass flow controller|
    US5820262A|1996-12-05|1998-10-13|Johnson Service Company|Smart refrigerant sensor|US20040025598A1|2000-09-21|2004-02-12|Festo Ag & Co.|Integrated fluid sensing device|
    DE10126821C1|2001-06-01|2003-02-20|Draeger Medical Ag|Valve arrangement for regulating the flow rate of a gas|
    US6769299B2|2003-01-08|2004-08-03|Fetso Corporation|Integral dual technology flow sensor|
    US6843139B2|2003-03-12|2005-01-18|Rosemount Inc.|Flow instrument with multisensors|
    JP4204400B2|2003-07-03|2009-01-07|忠弘 大見|Differential pressure type flow meter and differential pressure type flow control device|
    US6901794B2|2003-10-16|2005-06-07|Festo Corporation|Multiple technology flow sensor|
    CN102640070B|2009-12-01|2015-04-22|株式会社富士金|Pressure-type flow rate control device|
    JP5887188B2|2012-04-12|2016-03-16|株式会社堀場エステック|Fluid control equipment|
    SG11201507088YA|2013-03-08|2015-10-29|Fujikin Kk|Fluid control apparatus and thermal sensor installation structure with respect to fluid control apparatus|
    JP6106773B2|2016-01-28|2017-04-05|株式会社堀場エステック|Flow rate measuring device and flow rate control device|
    WO2017145966A1|2016-02-24|2017-08-31|株式会社バルコム|Pressure sensor|
    RU2682540C9|2018-08-22|2019-07-08|Александр Александрович Калашников|The method of setting the flow measurement channel with a restriction device|
    法律状态:
    2001-01-19| AS| Assignment|Owner name: SMC KABUSHIKI KAISHA, JAPAN Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:KUROSAWA, KENICHI;REEL/FRAME:011463/0253 Effective date: 20001212 |
    2003-04-24| STCF| Information on status: patent grant|Free format text: PATENTED CASE |
    2006-11-09| FPAY| Fee payment|Year of fee payment: 4 |
    2010-11-04| FPAY| Fee payment|Year of fee payment: 8 |
    2014-11-06| FPAY| Fee payment|Year of fee payment: 12 |
    优先权:
    申请号 | 申请日 | 专利标题
    JP2000012127A|JP2001201414A|2000-01-20|2000-01-20|Combined sensor and flow controller provided with the combined sensor|
    JP2000-012127||2000-01-20||
    [返回顶部]