Embodiments of the present invention relate to a sampling apparatus having one or more support structures and two or more sampling molds operatively coupled to the one or more support structures. The two or more sampling molds may be sealed or unsealed. The sampling apparatus is pressurized with a gas and immersed in the molten metal. The two or more sampling molds become unsealed when the mold stops at least partially melt. When the sampling apparatus is depressurized the one or more unsealed sampling molds capture one or more molten metal samples. The sampling apparatus is removed from the molten metal and the samples are removed from the sampling molds and analyzed.

An electrically passive device and method for in-situ acoustic emission, and/or releasing, sampling and/or measuring of a fluid or various material(s) is provided. The device may provide a robust timing mechanism to release, sample and/or perform measurements on a predefined schedule, and, in various embodiments, emits an acoustic signal sequence(s) that may be used for triangulation of the device position within, for example, a hydrocarbon reservoir or a living body.

An electrically passive device and method for in-situ acoustic emission, and/or releasing, sampling and/or measuring of a fluid or various material(s) is provided. The device may provide a robust timing mechanism to release, sample and/or perform measurements on a predefined schedule, and, in various embodiments, emits an acoustic signal sequence(s) that may be used for triangulation of the device position within, for example, a hydrocarbon reservoir or a living body.

A water sampling device has a rigid body, a top lid, extension members, a horizontal member, a spring, a rod, at least one polymer membrane and a bottom lid. The top lid has a shaft attached to it and the shaft traverses through the horizontal member. The bottom lid is connected to the rod upon which the at least one polymer membrane is attached perpendicularly. The water sampling device undergoes two different stages of lid opening and closing while in operation of collecting water sample to concentrate diversified bacteria from different water depths. The top lid, the shaft and the spring co-operate with the rigid body and the horizontal member such that in a first state, the top lid seals the top end opening while in a second state allows fluid to flow to an inside portion of the rigid body.

A method of, and apparatus for sampling a solid or liquid sample using a sampling tool which has a sampling rod/tube that is configured to house a sampling pod, the apparatus comprising: a main body portion with at least one sample collecting cavity; and a removable/opening lid portion that in use fits/closes over at least part of said main body portion and thereby covers and the cavity; the method further comprising the following steps: Inserting said sampling pod main body portion within said sampling rod/tube and taking a solid or liquid sample from a vessel/container; removing sampling rod/tube from said vessel or container and covering said collecting cavity to seal said cavity; transporting said sample within said sampling pod to place of a analysis; and at place of analysis removing at least part of said covering from main body portion to expose sample for analysis.

A method of, and apparatus for sampling a solid or liquid sample using a sampling tool which has a sampling rod/tube that is configured to house a sampling pod, the apparatus comprising: a main body portion with at least one sample collecting cavity; and a removable/opening lid portion that in use fits/closes over at least part of said main body portion and thereby covers and the cavity; the method further comprising the following steps: Inserting said sampling pod main body portion within said sampling rod/tube and taking a solid or liquid sample from a vessel/container; removing sampling rod/tube from said vessel or container and covering said collecting cavity to seal said cavity; transporting said sample within said sampling pod to place of a analysis; and at place of analysis removing at least part of said covering from main body portion to expose sample for analysis.

An apparatus for collecting a dry material sample flowing in a duct is disclosed. The apparatus includes a sample tube having a closed distal end and a sample-inlet aperture in the wall of the sample tube adjacent the closed distal end, a housing configured as a fluid cylinder with a duct end and an outlet end and a piston mounted around and connected to the sample tube and positioned within the housing. The apparatus also includes first and second sealing sleeves around and slideably supporting the sample tube. The duct end includes the first sealing sleeve and the outlet end includes the second sealing sleeve. A duct-connecting structure extends between the duct end of the housing and the duct. The sample tube is a piston rod within the fluid-cylinder housing, and the fluid-cylinder housing is configured to extend and retract the sample tube within the duct.

An apparatus for collecting a dry material sample flowing in a duct is disclosed. The apparatus includes a sample tube having a closed distal end and a sample-inlet aperture in the wall of the sample tube adjacent the closed distal end, a housing configured as a fluid cylinder with a duct end and an outlet end and a piston mounted around and connected to the sample tube and positioned within the housing. The apparatus also includes first and second sealing sleeves around and slideably supporting the sample tube. The duct end includes the first sealing sleeve and the outlet end includes the second sealing sleeve. A duct-connecting structure extends between the duct end of the housing and the duct. The sample tube is a piston rod within the fluid-cylinder housing, and the fluid-cylinder housing is configured to extend and retract the sample tube within the duct.

An ultra-deep reservoir stratified water sample and sediment core integrated artificial intelligence sampling device, comprising a sampling device main chamber, an attitude balance sensor, a propeller, a balance base, and a sampler body, wherein the attitude balance sensor and the sampler body are disposed inside the sampling device main chamber; the propeller is disposed outside the sampling device main chamber; and the balance base is located at a bottom end of the sampling device main chamber. The sampling device of the present invention is an intelligent sampling device integrating high-definition underwater topography observation, undisturbed sediment core collection, vertical stratified accurate sampling of water bodies, and real-time in-situ monitoring of key physical and chemical parameters, and can be flexibly applied to deep and shallow water environments under complicated conditions.

To provide a tubular body kit usable in stably preparing a liquid containing a desired component from blood or the like. The tubular body kit includes a tubular body, and a gasket movable in a tube axial direction in the tubular body, the tubular body includes a storage chamber partitioned by the gasket, the storage chamber being configured to store a liquid, and the gasket includes a first surface facing the storage chamber, the first surface having a flat surface shape or a recessed surface shape, the first surface including a first recessed portion.