Abstract: A sensor element includes a sensor chip and a diaphragm base joined to a surface of the sensor chip. The sensor chip includes a first diaphragm for measuring differential pressure between a first pressure and a second pressure and a second diaphragm for measuring absolute pressure or gage pressure of the second pressure. The diaphragm base includes a third diaphragm to directly receive a fluid that is a measurement target and has the first pressure, and a fourth diaphragm to directly receive a fluid that is a measurement target and having the second pressure. The sensor element has a liquid amount adjustment chamber to make an amount of a first pressure transmission medium filled in a first pressure introduction path and an amount of a second pressure transmission medium filled in a second pressure introduction path to be equal to each other.

Abstract: A sensor chip of a sensor element includes a diaphragm for measuring a differential pressure between a first pressure and a second pressure, a diaphragm for measuring an absolute pressure or a gauge pressure of the second pressure, a first pressure introduction path that transmits the first pressure to the diaphragm for measuring a differential pressure, and a second pressure introduction path that transmits the second pressure to the diaphragms. When the transmission of the first pressure or the second pressure to the diaphragms is indicated by an equivalent circuit, a path for transmitting the first pressure and a path for transmitting the second pressure are symmetrically formed.

Abstract: A differential pressure gauge of the invention contains: a diaphragm layer disposed between first and second parts; and a wall between a first region on a pressure-receiving portion side and a second region on a first through-hole side within a second pressure chamber. The diaphragm layer covers the pressure-receiving portion over a first pressure chamber and has the first through-hole with one end disposed in the second pressure chamber away from the pressure-receiving portion. The wall is disposed with gaps formed from inner walls of the second pressure chamber. The first pressure chamber is formed through the first part, the second pressure chamber has an opening facing the diaphragm layer, the first part has a second through-hole continuing to the first through-hole, and a base has a third through-hole with one end disposed in the first pressure chamber and a fourth through-hole continuing to the second through-hole.

Abstract: A curved recess in a stopper includes a groove-pattern region and a groove-free region. When a sensor diaphragm reaches a bottom of the curved recess in the stopper, a groove-free region is divided into a ring-shaped first region with which a sensor diaphragm is in close contact and a ring-shaped second region disposed between an inner wall surface of a ring-shaped wall and the ring-shaped first region. The first region serves as a sealing region and the second region serves as a confinement region so that a pressure transmitting medium that remains in a space adjacent to the inner wall surface of the ring-shaped wall is confined in the confinement region, and abnormal deformation of the sensor diaphragm is prevented.

Abstract: A sensor chip (24) is joined to an inner wall surface (20a) of a base body (21-1), with a lower surface (24a) of a first retaining member (24-2) serving as a joint surface, in such a manner as to allow an enclosing chamber (23) (including a pressure receiving chamber (23-1) and a pressure guiding passage (23-2)) between a pressure receiving diaphragm (22) and the joint surface (24a) of the sensor chip (24) to communicate with a pressure guiding hole (24-2b) in the first retaining member (24-2). In this state, a narrow tube (31) made of stainless steel is passed through the pressure guiding passage (23-2) in the base body (21-1) and inserted and secured in the pressure guiding hole (24-2b) in the first retaining member (24-2).

Abstract: A flow rate measurement error is reduced by a differential pressure type flowmeter that includes: a pipe; a laminar flow element disposed within the pipe; a first absolute pressure sensor measuring an absolute pressure P1 of a fluid upstream of the laminar flow element; a second absolute pressure sensor measuring an absolute pressure P2 of the fluid downstream; a temperature sensor measuring an ambient temperature T of the absolute pressure sensors; a pressure calculation section correcting an output signal from the first absolute pressure sensor based on the temperature T to be converted into the absolute pressure P1, and correcting an output signal from the second absolute pressure sensor based on the temperature T to be converted into the absolute pressure P2; and a flow rate calculation section calculating a flow rate of the fluid based on the absolute pressures P1 and P2 calculated by the pressure calculation section.

Abstract: The differential pressure gauge includes a base, a first part disposed on an upper surface of the base, a second part disposed on the first part, and a diaphragm layer disposed between the first part and the second part. A wall is formed in a second pressure chamber formed in the second part between a first region on a side including a pressure-receiving portion and a second region on a side including a first through-hole, with a gap defined with respect to inner walls of the second pressure chamber.

Abstract: A sensor chip (24) is joined to an inner wall surface (20a) of a base body (21-1), with a lower surface (24a) of a first retaining member (24-2) serving as a joint surface, in such a manner as to allow an enclosing chamber (23) (including a pressure receiving chamber (23-1) and a pressure guiding passage (23-2)) between a pressure receiving diaphragm (22) and the joint surface (24a) of the sensor chip (24) to communicate with a pressure guiding hole (24-2b) in the first retaining member (24-2). In this state, a narrow tube (31) made of stainless steel is passed through the pressure guiding passage (23-2) in the base body (21-1) and inserted and secured in the pressure guiding hole (24-2b) in the first retaining member (24-2).

Abstract: A sensor chip of a sensor element includes a diaphragm for measuring a differential pressure between a first pressure and a second pressure, a diaphragm for measuring an absolute pressure or a gauge pressure of the second pressure, a first pressure introduction path that transmits the first pressure to the diaphragm for measuring a differential pressure, and a second pressure introduction path that transmits the second pressure to the diaphragms. When the transmission of the first pressure or the second pressure to the diaphragms is indicated by an equivalent circuit, a path for transmitting the first pressure and a path for transmitting the second pressure are symmetrically formed.

Abstract: A sensor element includes a first diaphragm for measuring differential pressure between first pressure and second pressure and a second diaphragm for measuring absolute pressure or gage pressure of the second pressure. The sensor element has a first pressure introduction path (through holes, a groove, and a depression) through which the first pressure is transmitted to the first diaphragm. The sensor element has a second pressure introduction path (through holes, grooves, and depressions) through which the second pressure is transmitted to the first and second diaphragms. The sensor element has a liquid amount adjustment chamber (depression) configured to make an amount of a first pressure transmission medium filled in the first pressure introduction path and an amount of a second pressure transmission medium filled in the second pressure introduction path to be equal to each other.

Abstract: A sensor element includes diaphragms that are respectively displaced by receiving pressures, and a plurality of pressure inlet passages (a first pressure inlet passage made up of through-holes, a groove, and recessed portions, and a second pressure inlet passage made up of a through-hole, a groove, and a recessed portion) that respectively transmit same or different pressures to the diaphragms. Each of the plurality of pressure inlet passages is filled with a pressure transmission medium capable of transmitting a pressure. A pressure is applied through part or all of the plurality of pressure inlet passages to each of the diaphragms.

Abstract: A curved recess in a stopper includes a groove-pattern region and a groove-free region. When a sensor diaphragm reaches a bottom of the curved recess in the stopper, a groove-free region is divided into a ring-shaped first region with which a sensor diaphragm is in close contact and a ring-shaped second region disposed between an inner wall surface of a ring-shaped wall and the ring-shaped first region. The first region serves as a sealing region and the second region serves as a confinement region so that a pressure transmitting medium that remains in a space adjacent to the inner wall surface of the ring-shaped wall is confined in the confinement region, and abnormal deformation of the sensor diaphragm is prevented.

Abstract: A pressure sensor comprising: a sensor chip; a differential pressure diaphragm provided in the center portion of the sensor chip; a differential pressure gauge provided in the differential pressure diaphragm; a static pressure diaphragm provided at the outer peripheral portion of the differential pressure diaphragm; a first static pressure gauge formed at an edge portion of the static pressure diaphragm; and a second static pressure gauge formed at a center portion of the static pressure diaphragm.

Abstract: A pressure sensor including a sensor chip; a differential pressure diaphragm provided in the center portion of the sensor chip; a first differential pressure gauge formed along a radial direction relative to the center of the differential pressure diaphragm, provided on a first edge of the differential pressure diaphragm; a second differential pressure gauge formed along a circumferential direction, which is perpendicular to the radial direction, provided in the vicinity of the first differential pressure gauge on the first edge of the differential pressure diaphragm; and a static pressure diaphragm disposed between an edge portion of the sensor chip and one of the edges, other than the first edge, of the differential pressure diaphragm, provided to the outside of the differential pressure diaphragm.

Abstract: A pressure sensor comprising: a sensor chip; a differential pressure diaphragm provided in the center portion of the sensor chip; a differential pressure gauge provided in the differential pressure diaphragm; a static pressure diaphragm provided at the outer peripheral portion of the differential pressure diaphragm; a first static pressure gauge formed at an edge portion of the static pressure diaphragm; and a second static pressure gauge formed at a center portion of the static pressure diaphragm.

Abstract: A pressure sensor including a sensor chip; a differential pressure diaphragm provided in the center portion of the sensor chip; a first differential pressure gauge formed along a radial direction relative to the center of the differential pressure diaphragm, provided on a first edge of the differential pressure diaphragm; a second differential pressure gauge formed along a circumferential direction, which is perpendicular to the radial direction, provided in the vicinity of the first differential pressure gauge on the first edge of the differential pressure diaphragm; and a static pressure diaphragm disposed between an edge portion of the sensor chip and one of the edges, other than the first edge, of the differential pressure diaphragm, provided to the outside of the differential pressure diaphragm.