A microorganism sampling device includes: a head part that has a water supply channel to which a water supply pipe for supplying sample water can be connected; a housing part to an upper part of which the head part can be detachably attached; a frame-structured tube; a tubular filter that is arranged within the tubular body; a cup that communicates with the tubular filter and is attached to one end of the tube body; and a cap that has a channel communicating with the tubular filter and is attached to the other end of the tube body. The microorganism sampling device further includes a filter part housed in the housing part, in which a bottom part of the cup is supported by a bottom part of the housing part. The head part is attached to an upper part of the housing part.

The present invention describes an automatic propagation material sampling system, a propagation material sampling automation process and propagation material sampling equipment. More specifically, the present invention comprises a machine for anti-contaminating captation of propagation material samples in a non-destructive way, that is, maintaining the ability of subsequent propagation of the sampled propagation material, transports and tracks the sample without its contamination with residues of other materials, as well as tracks samples with desirable characteristics. The present invention is located in the fields of agronomic engineering and automation engineering, focused on the area of sample testing automation.

The present invention describes an automatic propagation material sampling system, a propagation material sampling automation process and propagation material sampling equipment. More specifically, the present invention comprises a machine for anti-contaminating captation of propagation material samples in a non-destructive way, that is, maintaining the ability of subsequent propagation of the sampled propagation material, transports and tracks the sample without its contamination with residues of other materials, as well as tracks samples with desirable characteristics. The present invention is located in the fields of agronomic engineering and automation engineering, focused on the area of sample testing automation.

A trace analyte collection swab having a collection surface at least partially coated with a microscopically tacky substance to enhance pick-up efficiency is described. In embodiments, the truce analyte collection swab comprises a substrate including a surface having a trace analyte collection area and a coating disposed on the surface of the substrate in the trace analyte collection area. The coating is configured to be microscopically adhesive to collect particles of the trace analyte from a surface when the trace analyte collection area is placed against the surface. In one embodiment, the coating comprises Polyisobutylene.

A trace analyte collection swab having a collection surface at least partially coated with a microscopically tacky substance to enhance pick-up efficiency is described. In embodiments, the truce analyte collection swab comprises a substrate including a surface having a trace analyte collection area and a coating disposed on the surface of the substrate in the trace analyte collection area. The coating is configured to be microscopically adhesive to collect particles of the trace analyte from a surface when the trace analyte collection area is placed against the surface. In one embodiment, the coating comprises Polyisobutylene.

A method for generating material test samples for conducting material tests of a legacy steam turbine rotor having an inter-blade region rotor surface, and an inlet region rotor surface adjoining the inter-blade region rotor surface. The method includes forming an annular ring of rotor material in the sample area and forming a material test sample from a portion of the annular ring. Also described is a legacy steam turbine rotor including an inter-blade region rotor surface, and an inlet region rotor surface adjoining the inter-blade region rotor surface. The steam turbine rotor having a groove formed therein, and wherein the groove is machined to enable removal of material from the steam turbine rotor to form samples configured to enable at least one of conducting material property tests and operating the improved legacy steam turbine rotor at an expanded thermal stress compared to the legacy steam turbine rotor.

Devices, systems, and methods for trapping and manipulating portions of tissue are described. In an embodiment, the devices include an array of traps, wherein traps of the array of traps are shaped to trap a tissue sample; and a well is in registry and fluidic communication with a trap of the array of traps.

In this invention it is disclosed a remote-controlled vehicle for operations in the extreme conditions (10) which comprises a base vehicle (100), a gripper (200), a manipulator arm (300), a mission module wherein base vehicle comprises front (110) and rear part (120), wherein on the front part of the base vehicle gripper is mounted and on the rear part of the base vehicle the manipulator arm is mounted and when in operation, the gripper and the manipulator arm are remotely operated. Also, it is disclosed whole system for remote operations comprising said remote-controlled vehicle and a control centre comprising a set of graphical user interfaces (GUI) and video displays (VD) arranged so that two way communication between the vehicle and control centre is established and wherein from GUI person can control and operate with the vehicle.

In this invention it is disclosed a remote-controlled vehicle for operations in the extreme conditions (10) which comprises a base vehicle (100), a gripper (200), a manipulator arm (300), a mission module wherein base vehicle comprises front (110) and rear part (120), wherein on the front part of the base vehicle gripper is mounted and on the rear part of the base vehicle the manipulator arm is mounted and when in operation, the gripper and the manipulator arm are remotely operated. Also, it is disclosed whole system for remote operations comprising said remote-controlled vehicle and a control centre comprising a set of graphical user interfaces (GUI) and video displays (VD) arranged so that two way communication between the vehicle and control centre is established and wherein from GUI person can control and operate with the vehicle.

A device for sand sampling through a water method includes a sampling cylinder and a triaxial sampler, where the sampling cylinder includes a cylinder, two ends of the cylinder being hermetically provided with an upper sealing cover and a lower sealing cover separately, one ends, facing inside of the cylinder, of the upper sealing cover and the lower sealing cover being provided with water-permeable stones, one end, facing outside of the cylinder, of the upper sealing cover being connected to a control valve, and the control valve being in communication with the inside of the cylinder; and the sampling cylinder is arranged in the triaxial sampler when sand sampling is performed through a water method, a lower end of the triaxial sampler is provided with a test operation table, and an upper end of the triaxial sampler is nested inside a restraint ring.