A horological setting and/or adjustment mechanism, including a setting and/or adjustment module (400) for a horological setting machine (1000), for making a setting and/or adjustment on a horological assembly (1), including an elastic clamp (600) with clamp arms (601) arranged to drive or deform a mobile component or a component of this assembly (1), the clamp (600) including a bearing portion (602) subjected to the action of an actuator, spindle (407), eccentric or push-piece, any deformation of this bearing portion (602) modifying the relative mutual position of the arms (601), and this setting and/or adjustment module (400) includes setting and/or adjustment means which include a plurality of motorised axes which are arranged to move, open and close, in a plane perpendicular to a clamp rotation direction (DF), a said clamp (600).

A horological setting and/or adjustment mechanism, including a setting and/or adjustment module (400) for a horological setting machine (1000), for making a setting and/or adjustment on a horological assembly (1), including an elastic clamp (600) with clamp arms (601) arranged to drive or deform a mobile component or a component of this assembly (1), the clamp (600) including a bearing portion (602) subjected to the action of an actuator, spindle (407), eccentric or push-piece, any deformation of this bearing portion (602) modifying the relative mutual position of the arms (601), and this setting and/or adjustment module (400) includes setting and/or adjustment means which include a plurality of motorised axes which are arranged to move, open and close, in a plane perpendicular to a clamp rotation direction (DF), a said clamp (600).

A method of controlling a needle actuator to interact with a cell is provided, the method comprising: providing an actuator comprising a tower, a stage and a needle, wherein the needle is mounted on the stage; applying an electrostatic potential between the tower and the stage to retract the needle; moving the actuator towards the cell; reducing the potential so as to allow the stage and needle to move towards the cell; applying calibration data to detect when the needle has pierced the cell; and reducing the potential further once it has been detected that the needle has pierced the cell. The cell can be a biological cell. The needle can be a micro-needle and the stage can be a micro-stage.

A method of controlling a needle actuator to interact with a cell is provided, the method comprising: providing an actuator comprising a tower, a stage and a needle, wherein the needle is mounted on the stage; applying an electrostatic potential between the tower and the stage to retract the needle; moving the actuator towards the cell; reducing the potential so as to allow the stage and needle to move towards the cell; applying calibration data to detect when the needle has pierced the cell; and reducing the potential further once it has been detected that the needle has pierced the cell. The cell can be a biological cell. The needle can be a micro-needle and the stage can be a micro-stage.

The purpose of the present invention is to collect a plurality of microscopic objects dispersed in a liquid by light irradiation, and also trap them. A collecting device for bacteria collects a plurality of bacteria dispersed in a sample liquid. The collecting device is provided with a laser beam source that emits laser beam and a honeycomb polymer film constituted so as to be able to hold the liquid. Walls prescribing pores for trapping the plurality of bacteria dispersed in the liquid are formed on the honeycomb polymer film, and also a thin film that includes a material for converting light from the laser beam source to heat is formed on the honeycomb polymer film. The thin film heats the liquid of the sample through the conversion of the laser beam from the laser beam source to heat, thereby causing a convection in the liquid.

A nanoscale positioning apparatus with a large stroke and multiple degrees of freedom and a control method thereof are provided. The nanoscale positioning apparatus includes a base, a plurality of parallel branch chain mechanisms and a working table. Each of the parallel branch chain mechanisms includes an electric cylinder, a micro-motion drive mechanism, a laser interferometer, a grating measuring device, a self-locking upper hinge and a self-locking lower hinge. The top of the base is connected to one end of the electric cylinder through the self-locking lower hinge. The other end of the electric cylinder is connected to one end of the micro-motion drive mechanism. The other end of the micro-motion drive mechanism is connected to the bottom of the working table through the self-locking upper hinge. The positioning apparatus has multiple degrees of freedom, and realizes multi-degree-of-freedom arbitrary position adjustment of the working table through parallel branch chain mechanisms.

A method and a novel flexure interface apparatus are provided for ultrahigh-vacuum (UHV) applications for precision nanopositioning systems. An ultrahigh-vacuum (UHV) metrology base is integrated with an ultrahigh-vacuum (UHV) flange together including a precision and compact flexure interface structure defining a UHV metrology base near-zero-length feedthrough. The UHV metrology base is directly mounted to a flange mounting surface in air with nanopositioning and thermal stability. The precision and compact flexure interface structure has sufficient strength to hold the vacuum force and sufficiently flexible to survive with the thermal expansion stress during bakeout process.

A device for a microactuator comprises a body (110), two terminal members (20, 22) articulated (136, 138) on the body (110), which are situated on one side of the latter, and two deformable bowl-shaped walls (120, 122) which face one another. The walls are configured to house an actuator, with two respective first edges (1202, 1222) of these walls (120, 122) situated on one side being fixed (1264) to the body (110), whereas two respective second edges (1204, 1224) of these walls (120, 122) situated on another side move consecutively to a deformation of the walls (120, 122) under the effect of the actuator. This movement is transmitted by two arms (132, 134) which terminate at the two respective terminal members (20, 22).

A device for a microactuator comprises a body (110), two terminal members (20, 22) articulated (136, 138) on the body (110), which are situated on one side of the latter, and two deformable bowl-shaped walls (120, 122) which face one another. The walls are configured to house an actuator, with two respective first edges (1202, 1222) of these walls (120, 122) situated on one side being fixed (1264) to the body (110), whereas two respective second edges (1204, 1224) of these walls (120, 122) situated on another side move consecutively to a deformation of the walls (120, 122) under the effect of the actuator. This movement is transmitted by two arms (132, 134) which terminate at the two respective terminal members (20, 22).

An electromechanical microsystem including an electromechanical transducer, a deformable diaphragm, a first cavity hermetically containing a deformable medium keeping a substantially constant volume under the action of an external pressure change and a second cavity. The deformable diaphragm forms a wall of the cavity and has at least one area freely deformable elastically. The free area also forms a wall of the second cavity. The electromechanical transducer is configured so that its movement depends on the external pressure change, and vice versa. A change in the external pressure in the first cavity induces a variation of the volume of the second cavity, or vice versa. Thus, the proposed electromechanical microsystem enables gripping of an object obstructing the opening of the second cavity and forms a microbarometer capable of converting at least one ambient pressure change into an electrical signal.