The present invention provides a surface following nozzle, an observation device for a moving object surface, and an observation method for the moving object surface that can remove water in the vicinity of the nozzle while following changes in the shape and changes in the distance of a moving object. A surface following nozzle includes a nozzle that injects gas from a tip end thereof, a separating part that closes a base end of the nozzle, and an extending and contracting part that is provided at a rear side of the nozzle via the separating part, and extends and contracts along an axial direction of the nozzle. The extending and contracting part includes an elastic body that applies a forward force with respect to the nozzle.

The invention relates to a device for monitoring the contact of a workpiece (1) or tool on a spindle (2) of a machine tool, which device has a contact surface (3) for the workpiece (1) or tool. At least one measurement nozzle (4) is arranged in the region of the contact surface in order to produce a fluid flow directed away from the contact surface (3). Upstream of the measurement nozzle, the fluid flow is conducted through a vacuum nozzle, which can comprise a jet nozzle (7c) and a collector nozzle (7b). When the fluid medium flows through the vacuum nozzle, the vacuum nozzle produces a negative pressure in a negative pressure chamber (9c). A pressure sensor (6) or pressure switch senses a measurement pressure (p3) in the negative pressure chamber.

The invention relates to a device for monitoring the contact of a workpiece (1) or tool on a spindle (2) of a machine tool, which device has a contact surface (3) for the workpiece (1) or tool. At least one measurement nozzle (4) is arranged in the region of the contact surface in order to produce a fluid flow directed away from the contact surface (3). Upstream of the measurement nozzle, the fluid flow is conducted through a vacuum nozzle, which can comprise a jet nozzle (7c) and a collector nozzle (7b). When the fluid medium flows through the vacuum nozzle, the vacuum nozzle produces a negative pressure in a negative pressure chamber (9c). A pressure sensor (6) or pressure switch senses a measurement pressure (p3) in the negative pressure chamber.

The present disclosure is directed toward a method for measuring a seal gap between a closing member and a fixed member. The method includes applying a liquid agent having transferable properties along one or more regions of a stamping member to form one or more base marks. The stamping member is one of the closing member or the fixed member. The method further includes engaging the closing member with the fixed member, disengaging the closing member from the fixed member, and assessing a seal gap between the closing member and the fixed member based on one or more remnant patterns formed on an imprinted member. The imprinted member is the other one of the closing member and the fixed member, and the remnant patterns are formed by the transfer of the liquid agent from the base marks.

The present disclosure is directed toward a method for measuring a seal gap between a closing member and a fixed member. The method includes applying a liquid agent having transferable properties along one or more regions of a stamping member to form one or more base marks. The stamping member is one of the closing member or the fixed member. The method further includes engaging the closing member with the fixed member, disengaging the closing member from the fixed member, and assessing a seal gap between the closing member and the fixed member based on one or more remnant patterns formed on an imprinted member. The imprinted member is the other one of the closing member and the fixed member, and the remnant patterns are formed by the transfer of the liquid agent from the base marks.

A measuring device (10) for measuring the space remaining after a side crash has a pneumatic piston rod cylinder (20) with a cylinder (22), and a piston rod (24) that can move relative to the cylinder (22). A measuring unit (40) measures the movement (26) of the piston rod (24) relative to the cylinder (22), and a base part (12) positions the piston rod cylinder (20). The piston rod cylinder (20) can be connected to a pressure vessel (70) to permit the piston rod (24) to move out when a fluid is applied to the piston rod cylinder (20).

A measuring device (10) for measuring the space remaining after a side crash has a pneumatic piston rod cylinder (20) with a cylinder (22), and a piston rod (24) that can move relative to the cylinder (22). A measuring unit (40) measures the movement (26) of the piston rod (24) relative to the cylinder (22), and a base part (12) positions the piston rod cylinder (20). The piston rod cylinder (20) can be connected to a pressure vessel (70) to permit the piston rod (24) to move out when a fluid is applied to the piston rod cylinder (20).

A gas gauge proximity sensor comprising a measurement gas flow channel having an optical pressure sensor for comparing a pressure of the first gas flow and a reference pressure; the optical pressure sensor comprising a first optical cavity fluidly connected to the measurement channel and a second optical cavity fluidly connected to the reference pressure, with the optical cavities being configured to receive electromagnetic radiation and output reflected electromagnetic radiation, the optical pressure sensor further being configured to combine the reflected electromagnetic radiation from the first optical cavity with the reflected electromagnetic radiation from the second optical cavity and determine, based on the combined electromagnetic radiation, a pressure difference between the pressure of the first gas flow and the reference pressure and determine, based on the pressure difference, a distance between the measurement outlet and the measurement object.

A gas gauge proximity sensor comprising a measurement gas flow channel having an optical pressure sensor for comparing a pressure of the first gas flow and a reference pressure; the optical pressure sensor comprising a first optical cavity fluidly connected to the measurement channel and a second optical cavity fluidly connected to the reference pressure, with the optical cavities being configured to receive electromagnetic radiation and output reflected electromagnetic radiation, the optical pressure sensor further being configured to combine the reflected electromagnetic radiation from the first optical cavity with the reflected electromagnetic radiation from the second optical cavity and determine, based on the combined electromagnetic radiation, a pressure difference between the pressure of the first gas flow and the reference pressure and determine, based on the pressure difference, a distance between the measurement outlet and the measurement object.

The invention relates to a device and a method for a contactless analysis of a product, in particular for the contactless analysis of a dough product. The device comprises a distance sensor configured for measuring a distance between the device and the product, and a nozzle configured for directing a jet of pressurized fluid to a position on a surface of said product. The distance sensor is arranged for measuring the distance between the device and the position of the surface where the jet of pressurized fluid is directed to. Preferably, the distance sensor is at least partially arranged in the nozzle, preferably substantially in the center of said nozzle.