Abstract: A pressure-type flow controller includes a main body provided with a fluid channel between a fluid inlet and a fluid outlet and an exhaust channel between the fluid channel and an exhaust outlet; a pressure control valve fixed to the fluid inlet of the main body for opening/closing the upstream side of the fluid channel; a pressure sensor for detecting the internal pressure of the fluid channel on the downstream side of the pressure control valve; an orifice provided in the fluid channel on the downstream side of the point of branching of the exhaust channel; and an exhaust control valve for opening/closing the exhaust channel.

Abstract: A pressure-type flow rate control device includes a control valve; a pressure sensor provided downstream of the control valve; an orifice-built-in valve provided downstream of the pressure sensor; and a control unit connected to the control valve and pressure sensor. The built-in orifice valve has a valve mechanism comprising a valve seat body and a valve element for opening/closing a flow path; a drive mechanism for driving the valve mechanism, and an orifice member provided in the vicinity of the valve mechanism. The pressure-type flow rate control device further includes an opening/closing-detection mechanism for detecting the open/closed state of the valve mechanism, the control unit being configured to receive a detection signal from the opening/closing-detection mechanism.

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 pressure-type flow rate controller includes a body provided with a fluid passage which communicates a fluid inlet and a fluid outlet, a control valve for pressure control fixed to the body to open and close the fluid passage, an orifice arranged in the course of the fluid passage on the downstream side of the control valve, and a pressure sensor fixed to the body to detect the internal pressure of the fluid passage between the control valve and the orifice, wherein the fluid passage comprises a first passage portion communicating the control valve and a pressure detection chamber provided on a pressure detection surface of the pressure sensor, and a second passage portion spaced away from the first passage portion and communicating the pressure detection chamber and the orifice.

Abstract: An inline concentration meter includes a light source unit emitting mixed light containing at least two wavelengths with a phase difference, a detecting unit including a light incident part for entering the mixed light emitted from the light source unit into a fluid passage of a detector body and at least two light detection parts receiving the mixed light passed through the fluid passage, a computing processor unit conducting frequency analyzes of detection signals of the mixed light output from the respective light detection parts and computing variations of intensities of the detection signals corresponding to absorbances in at least two frequency ranges to compute a concentration of fluid in the fluid passage based on the variations of the intensities of the detection signals, and a recording/displaying unit recording and displaying a value of the fluid concentration computed at the computing processor unit.

Abstract: A pressure-type flow rate control device 1, while maintaining an upstream pressure P1 of an orifice 5 at approximately at least twice a downstream pressure P2, calculates a flow factor FF of a mixed gas consisting of two types of gases mixed at a mixture ratio of X:(1?X) by FF=(k/?){2/(?+1)}1/(??1)[?/{(?+1)R}]1/2 using an average density ?, an average specific heat ratio ?, and an average gas constant R of the mixed gas that are calculated by weighting the densities, specific heat ratios, and gas constants of the two types of gases at the mixture ratio, and calculates a flow rate Q of the mixed gas passing through the orifice by Q=FF·S·P1(1/T1)1/2, where S is the orifice cross section, and P1 and T1 are respectively the pressure and temperature of the mixed gas on the upstream side of the orifice.

Abstract: A substrate processing system includes a gas supply unit having a first gas flow channel. A second gas flow channel of a flow rate measurement system is connected to the first gas flow channel. The flow rate measurement system further includes a third gas flow channel connected to the second gas flow channel, and a pressure sensor and a temperature sensor that measure a pressure and a temperature, respectively, in the third gas flow channel. In a method of an embodiment, a flow rate of a gas output from a flow rate controller of the gas supply unit is calculated using a build-up method. The flow rate of a gas is calculated without using the total volume of the first gas flow channel and the second gas flow channel and temperatures in the first gas flow channel and the second gas flow channel.

Abstract: A concentration measurement device including at least one light source; a measurement cell for containing a fluid to be measured; a splitter for dividing light from the light source into incident light being incident into the measurement cell and non-incident light not being incident into the measurement cell; a transmitted-light detector for detecting transmitted light that is the incident light having passed through the measurement cell; a non-incident light detector for detecting the non-incident light; and an arithmetic part for correcting a detection signal of the transmitted-light detector using a detection signal of the non-incident light detector.

Abstract: A valve with a built-in orifice includes a base section having a housing recess and first and second flow passages; a valve seat body; an inner disc; a valve element; and an orifice body, wherein the housing recess has a wide-diameter section and a narrow-diameter section, the first flow passage is connected to a space between a wall surface of the narrow-diameter section and the orifice body to communicate with a valve chamber, and the second flow passage communicates with the valve chamber through a through hole of the orifice body and a through hole of the valve seat body.

Abstract: A flow passage sealing structure for omitting a process of welding or caulking an orifice plate and a filter plate to an orifice base and a filter base as base materials and allowing further miniaturization, includes a main block (1) including main flow passages (1a, 1b), recessed portions (12, 13) provided in side surfaces of the main block and having female screws in inner peripheral surfaces, thin plates (6, 8) abutting against the bottom surfaces of the recessed portions and having through holes, gasket rings (16, 17) abutting against the thin plates (6, 8), pressing pipelines (20, 21) having large-diameter portions and internal flow passages communicable with the main flow passages (1a, 1b) and abutting against the gasket rings, and fastening screws (22) abutting against the large-diameter portions and pressing the pressing pipelines by being inserted around the outside of the pressing pipelines and screwed into the female screws.

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.

Abstract: A liquid level meter includes a first resistive temperature detector; a first temperature measuring body a liquid level detection section a temperature detection section detecting the temperatures of the first resistive temperature detector and the first temperature measuring body; a current control section determining a value of a current to apply to the first resistive temperature detector such that a difference between the temperatures of the first resistive temperature detector and the first temperature measuring body detected by the temperature detection section to be a first constant value; and a power supply unit supplying a current of the determined current value to the first resistive temperature detector; wherein the liquid level detection section determines whether the first resistive temperature detector is present in a liquid or outside of the liquid using the value of the current applied to the first resistive temperature detector.

Abstract: The pressure-type flow controller includes a main body provided with a fluid passage, a control valve for pressure control fixed in a horizontal position to the main body, an on/off valve fixed in a vertical position to the main body on the downstream side of the control valve for pressure control, an orifice provided in the fluid passage on the upstream side of the on/off valve, and a pressure sensor fixed to the main body for detecting the internal pressure of the fluid passage between the control valve for pressure control and the orifice. The fluid passage includes a first passage portion in a horizontal position connected to the control valve for pressure control, a second passage portion in a vertical position connecting the first passage portion to the orifice, and a third passage portion in a horizontal position connecting the second passage portion to the pressure sensor.

Abstract: A pressure-type flow rate control device includes a restriction part, a control valve disposed upstream of the restriction part, an upstream pressure sensor, a downstream pressure sensor, and a controller that diagnoses flow rate control by using pressure drop data on a flow passage between the control valve and the restriction part and reference pressure drop data, wherein a close command is issued to the control valve and a shutoff valve provided downstream of the downstream pressure sensor, and the controller determines whether a predetermined critical expansion condition is satisfied by using outputs of the upstream pressure sensor and the downstream pressure sensor after the control valve is closed, and diagnoses flow rate control by using the pressure drop data acquired during a period in which the predetermined critical expansion condition is satisfied.

Abstract: The flow controller according to the present invention includes: a control valve; a first flow passage provided on the downstream side of the control valve; a second flow passage; and an expansion chamber provided between the first flow passage and the second flow passage. The second flow passage is provided in a position that is not on the extension of the first flow passage.

Abstract: An inline concentration measurement device comprises: a measurement cell main body with a gas flow path formed; a light incident part with a window member connected to the main body; and a light receiving part with a window member connected to the main body, wherein the gas flow path includes a gas flow path for an optical path extending straight between the window members of the light incident part and the light receiving part, a first communication part making a gas inlet formed in the main body communicate with the gas flow path part for the optical path, and a second communication part making a gas outlet formed in the main body communicate with the gas flow path part for the optical path, and the first communication part obliquely extends from the gas inlet towards the window member of the light incident part.

Abstract: A gas supply system includes a flow controller, a first shutoff valve provided downstream of the flow controller, a second shutoff valve provided in a first flow passage communicating with the downstream side of the first shutoff valve, a second flow passage branching from the first flow passage, a third shutoff valve provided in the second flow passage, a pressure sensor that detects a pressure in a flow passage surrounded by the first, second, and third shutoff valves, a temperature sensor that detects a temperature in the flow passage, a volume measuring tank having a known volume connected downstream of the third shutoff valve, and a controller that obtains a volume of the flow passage by applying Boyle's law to open and closed states of the third shutoff valve and calculates the flow rate using the passage volume and outputs of the pressure and temperature sensors.

Abstract: A piezoelectric element-driven valve includes a body provided with a fluid channel and a valve seat, a valve element which opens and closes the fluid channel by being in contact with and separated from the valve seat of the body, and piezoelectric actuators which drive the valve element to open and close by means of the extension of the piezoelectric element. In the piezoelectric element-driven valve, at least two piezoelectric actuators are arranged on a straight line via a spacer which allows pulling out of wiring.

Abstract: A piezoelectric linear actuator includes a laminated piezoelectric actuator, a lower support member that supports the laminated piezoelectric actuator, a pressing member that biases the laminated piezoelectric actuator from the top thereof, a guide member connected to the lower support member to guide the pressing member; and a displacement transmission member which includes a pair of displacement transmission plates, an adjustment screw connected to the pair of displacement transmission plates, an output section connected to the pair of displacement transmission plates, and an elastic body that biases the output section downward.

Abstract: A flow rate signal correction method applicable to a pressure-type flow rate control device that controls a flow rate by controlling pressure existing upstream of a restriction part includes a step of generating a primary signal indicating the flow rate in accordance with an output of a pressure sensor provided upstream of the restriction part and a step of generating a secondary signal as a corrected signal of the primary signal such that the current value of the primary signal and a value including information regarding one or a plurality of past values of the primary signal are used to derive a current value corrected according to a predetermined relational expression. The secondary signal is output as a flow rate signal during a stable flow rate period, and the secondary signal is not output as a flow rate signal during a transient change period.