Abstract: A Concentration measurement device 100 comprises: a measurement cell 4 having a flow path through which a gas flows, a light source 1 for generating incident light to the measurement cell, a photodetector 7 for detecting light emitted from the measurement cell, a pressure sensor 20 for detecting a pressure of the gas in the measurement cell, a temperature sensor 22 for detecting a temperature of the gas in the measurement cell, and an arithmetic circuit 8 for calculating a concentration of the gas based on an output P of the pressure sensor, an output T of the temperature sensor, an output I of the photodetector, and an extinction coefficient ?, wherein the arithmetic circuit 8 is configured to calculate the concentration using the extinction coefficient ? determined on the basis of the output of the temperature sensor 22.

Abstract: A flow rate control method performed using a flow rate control device 100 comprising a first control valve 6 provided in a flow path, a second control valve 8 provided downstream of the first control valve, and a pressure sensor 3 for measuring fluid pressure downstream of the first control valve, the method comprising steps of: (a) closing the opening of the first control valve from a state in which, while controlling the opening of the first control valve based on an output of the pressure sensor so as to be the first flow rate, maintaining the opening of the second control valve in an open state, and flowing a fluid at the first flow rate; and (b) based on the output of the pressure sensor, the pressure remaining downstream of the first control valve is controlled by adjusting the opening of the second control valve, and flowing the fluid at the second flow rate downstream of the second control valve.

Abstract: A concentration measuring device 100 comprises: a measurement cell 4 having a flow path, a light source 1, a photodetector 7 for detecting light emitted from the measurement cell, and an arithmetic circuit 8 for calculating light absorbance and concentration of a fluid to be measured on the basis of an output of the photodetector, the measurement cell includes a cell body, a window portion 3 fixed to the cell body so as to contact the flow path, and a reflective member 5 for reflecting light incident on the measurement cell through the window portion, the window portion is fixed to the cell body 40 by a window holding member 30 via a gasket 15, an annular sealing protrusion 15a is provided on a first surface of the gasket for supporting the window portion, and an annular sealing protrusion 42a is also provided on a support surface 42 of the cell body for supporting the second surface opposite to the first surface of the gasket.

Abstract: A fluid control device includes a main body block including a first flow passage, and a second flow passage, a first and second fluid control units installed on an installation surface of the main body block. The first and second flow passages include a first portion extending along a first direction and a second flow passage portion orthogonal to the first direction. The second portion is formed of a hole extending from a side surface of the main body block and a sealing member.

Abstract: A fluid controller is provided having a flow path through which a fluid can flow, a closed space separated from the flow path by an isolation member, and a leak port capable of communicating the closed space with an external part. An anomaly detection device for detecting an anomaly has a pressure sensor detachably fixed to the leak port, a pressure sensor for detecting the pressure in the closed space, a processing module for executing a predetermined information processing, and an detachable mechanism for blocking the leak port from the external part in the state of being fixed. The processing module determines an anomaly of the fluid controller by comparing a detection value detected by the pressure sensor to a predetermined threshold, and transmits a discrimination result of the anomaly of the fluid controller to a server.

Abstract: A concentration measurement method is performed using a concentration measurement device comprising: a measurement cell for flowing a fluid to be measured; a light source for generating light incident on the measurement cell; a photodetector for detecting light emitted from the measurement cell; an arithmetic unit for calculating the absorbance and concentration of the fluid to be measured based on an output of the photodetector; and a temperature sensor for measuring the temperature of the fluid to be measured.

Abstract: A flow rate control method for raising a flow rate performed in a flow control device having a first control valve, a second control valve downstream of the first control valve, and a pressure sensor for measuring a pressure between the first and the second control valves, comprises a step (a) of determining a pressure remaining downstream of the first control valve in a state of closing the second control valve, and a step (b) of controlling the pressure remaining downstream of the first control valve by adjusting the opening degree of the second control valve based on the output of the pressure sensor to flow the fluid downstream the second control valve at the first flow rate.

Abstract: A concentration measurement device 100 includes a light source 22 for generating incident light to a measurement space 10A, a photodetector 24 for receiving light emitted from the measurement space, and an arithmetic control circuit 26 for calculating a concentration of a measurement fluid on the basis of an output of the photodetector, and the light source includes a first light-emitting element 22a for generating light having a first wavelength, and a second light-emitting element 22b for generating light having a second wavelength, and the concentration measurement device is configured so as to calculate the concentration using either light of the first wavelength or the second wavelength on the basis of the pressure or temperature of the measurement fluid.

Abstract: A control device for a valve device can detect open/close state of the valve device without using limit switches. The valve device includes a diaphragm for opening and closing a flow path for flowing a fluid, a coil spring for biasing the diaphragm in the closing direction of flow path, a main actuator for driving it against the biasing force of the coil spring, and an adjusting actuator using a piezoelectric element for adjusting the opening degree of the flow path determined by the diaphragm. The controller detects the open/close state of flow path based on the voltage generated by the piezoelectric element of the adjusting actuator, and controls valve device using the detection signal.

Abstract: A pressure sensor includes a cylindrical member configured to be attached to a body having a fluid passage, and a pressure sensor unit connected to the cylindrical member for detecting a pressure of a fluid flowing through the fluid passage, wherein the cylindrical member is made of a nickel-molybdenum-chromium alloy material or a stainless steel material, wherein the pressure sensor unit includes a sensor body closed at one end with a diaphragm and a pressure detecting element for outputting displacement of the diaphragm as pressure, and wherein the sensor body is made of a cobalt-nickel alloy material, and is connected at an opening side end portion to one end portion of the cylindrical member.

Abstract: A control unit 3 of a flow rate control system 1 comprises: a recording unit 31 for recording measured values of a pressure sensor P and a temperature sensor T, a storage unit 32 for storing volume data between a first valve V1 and a second valve V2 corresponding to the measured value of the pressure sensor P, and an arithmetic unit 33 for calculating a flow rate based on a first pressure value P1 and a first temperature value T1 measured after opening the first valve V1 and the second valve V2 to flow a gas and then closing the first valve V1 and the second valve V2 simultaneously in a state where the gas is flowing; a second pressure value P2 and a second temperature value T2 measured after opening the first valve V1 and the second valve V2 to flow a gas, closing the second valve V2 in a state where the gas is flowing, and then closing the first valve V1 after a predetermined time ?t has elapsed; and a volume value V between the first valve V1 and the second valve V2 which corresponds to the second pressure

Abstract: The fluid controller includes a fluid control module and an external control module. The fluid control module includes a control valve on a flow channel, a valve driver circuit that drives the control valve, a fluid meter on a flow channel, and a first processor that processes a signal output from the fluid meter. The external control module includes a second processor that processes a signal output from the first processor. The second processor outputs a valve control signal according to the signal of the fluid meter output from the first processor, the valve control signal is directly input to the valve driver circuit without through the first processor, and the valve driver circuit outputs a voltage that drives the control valve according to the valve control signal from the second processor.

Abstract: A piezoelectric element-driven valve 1 including a main body, a valve element, piezoelectric actuators, a plurality of cylindrical actuator boxes arranged in series, a cylindrical outer connecting jig detachably connecting the adjacent actuator boxes and having an opening for drawing out wiring, a plurality of piezoelectric actuators accommodated in the actuator box respectively in the same direction, and a cylindrical inner connecting jig slidably accommodated in the outer connecting jig and having an opening for positioning the adjacent piezoelectric actuators and drawing out wiring.

Abstract: A flow rate control method performed in a flow control device 100 having a first control valve 6 provided in the flow path, a second control valve 8 provided downstream of the first control valve, and a pressure sensor 3 for measuring a fluid pressure upstream of the first control valve and downstream of the second control valve, comprises, at the time of flow rate raise, a step (a) of determining a pressure remaining downstream of the first control valve by using a pressure sensor in a state of closing the second control valve, and a step (b) of controlling the pressure remaining downstream of the first control valve by adjusting the opening degree of the second control valve on the basis of the output from the pressure sensor, and flowing a fluid at the first flow rate downstream the second control valve.

Abstract: A flow rate control device (100) comprises: a pressure control valve (6) provided in a flow path; a flow rate control valve (8) provided downstream side of the pressure control valve; and a first pressure sensor (3) for measuring pressure on the downstream side of the pressure control valve and on the upstream side of the flow rate control valve. The flow rate control valve has a valve element (13) seated on/separated from a valve seat (12); a piezoelectric element (10b) for moving the valve element so as be seated on/separated from the valve seat; and a strain sensor (20) provided on a side surface of the piezoelectric element. The pressure control valve (6) is configured to control the pressure control valve (6) on the basis of a signal output from the first pressure sensor (3), and to control the driving of the piezoelectric element of the flow rate control valve (8) based on a signal output from the strain sensor (20).

Abstract: A piezoelectric-element-driven valve includes a valve seat provided on a flow path, a valving element detachably seated on the valve seat, and a piezoelectric element, and is configured to move the valve body by extension of the piezoelectric element. The piezoelectric-element-driven valve also is provided with a detection mechanism for detecting an extension amount of the piezoelectric element, the detection mechanism including a strain sensor, and being capable of detecting an movement amount of the valving element from an output of the strain sensor.

Abstract: A flow rate control method performed using a flow rate control device 100 comprising a first control valve 6 provided in a flow path, a second control valve 8 provided downstream of the first control valve, and a pressure sensor 3 for measuring fluid pressure downstream of the first control valve, the method comprising steps of: (a) closing the opening of the first control valve from a state in which, while controlling the opening of the first control valve based on an output of the pressure sensor so as to be the first flow rate, maintaining the opening of the second control valve in an open state, and flowing a fluid at the first flow rate; and (b) based on the output of the pressure sensor, the pressure remaining downstream of the first control valve is controlled by adjusting the opening of the second control valve, and flowing the fluid at the second flow rate downstream of the second control valve.

Abstract: A flow rate control device 100 includes a control valve 6 provided in a flow path 1, a flow rate measurement unit 2, 3 for measuring fluid flow rate controlled by the control valve 6, and a controller 7. The controller 7 is configured so as to control the opening/closing operation of the control valve 6 to match the measurement integral flow rate based on the signal outputted from the flow rate measurement unit (Vn+Vd) to the target integral flow rate Vs.

Abstract: A concentration measurement device for measuring the concentration of a measured fluid within a measurement cell by detecting transmitted light that has passed through the measurement cell having a light incidence window and a light emission window disposed opposing to each other, comprising a reflected-light detector for detecting reflected light of the light incidence window.

Abstract: In a method of calibrating a flow rate control device in which a flow rate is calibrated based on comparison with a flow rate measured by a flow rate reference gauge, a predetermined permissible error range is set for a plurality of flow rate settings, and the permissible error range of at least one specific flow rate setting among the plurality of flow rate settings is set to be smaller than the predetermined permissible error range.