A storage tube assembly, with a cap having a top surface and a sealing member connected to the top surface, the sealing member has a generally cylindrical upper wall and a generally cylindrical lower wall, the sealing member also has a recessed portion between the upper wall and lower wall and a flange cut into the lower wall; a sealing ring, the sealing ring is sized to cooperate with and be received in the recessed portion of the sealing member of the cap; and a tube, the tube has a generally circular inner wall with a cut therein, the cut in the inner wall is positioned to receive the sealing ring when the sealing ring is positioned within the recessed portion of the cap and the cap is placed into an open end of the tube.

An obturation element (1) for a well receiving a chemical or biological solution to be analyzed, including for each well, a plug (4) including an insertion sleeve (5) in the form of a cylinder provided with two truncated areas (15) arranged in a symmetrically opposite manner on the outside of the sleeve to form vents, this insertion sleeve (5) being provided with a bottom wall (9) in which a through-cutout (18) is arranged, oriented radially in the direction of the two truncated areas (15).

A plug for a container for storing liquid includes a housing having a longitudinal axis. A first sensor bank is arranged vertically in the housing along the longitudinal axis, the first sensor bank comprising a first printed circuit board (PCB) and a first sensor mounted on the first PCB. A first sensor chamber is inside the housing, the first sensor chamber having a first lateral side comprising the first PCB and a second lateral side comprising a second PCB or an interior wall of the housing. The plug also includes an input end of the housing and a first flow pathway between the input end and the first sensor chamber.

A plug for a container for storing liquid includes a housing having a longitudinal axis. A first sensor bank is arranged vertically in the housing along the longitudinal axis, the first sensor bank comprising a first printed circuit board (PCB) and a first sensor mounted on the first PCB. A first sensor chamber is inside the housing, the first sensor chamber having a first lateral side comprising the first PCB and a second lateral side comprising a second PCB or an interior wall of the housing. The plug also includes an input end of the housing and a first flow pathway between the input end and the first sensor chamber.

The invention relates to a system for automatic closure of sample vessels (PG), in particular of sample vessels (PG) with medical laboratory samples, with iii. a plurality of identically shaped, stackable closure caps (10) which have a convex outer face and a concave inner face and which are stacked in at least one closure cap stack in such a way that an upper closure cap (10) in the closure cap stack bears with its convex outer face on the concave inner face of a lower closure cap (10) lying immediately below in the closure cap stack, iv. a closure gripper (20) for gripping an uppermost closure cap (10) from the at least one closure cap stack, for transferring the gripped closure cap (10) to the sample vessel (PG) to be closed, and for introducing the gripped closure cap (10) into an opening of the sample vessel in order to tightly close the opening, wherein the closure gripper (20) has a centering piece which can be inserted into a closure cap (10) in such a way that it bears on the concave inner face of the closure cap (10). With such a system, automated closure of sample vessels is possible in a space-saving and efficient way. Furthermore, a method for automatic closure of sample vessels is also disclosed.

The invention relates to a system for automatic closure of sample vessels (PG), in particular of sample vessels (PG) with medical laboratory samples, with iii. a plurality of identically shaped, stackable closure caps (10) which have a convex outer face and a concave inner face and which are stacked in at least one closure cap stack in such a way that an upper closure cap (10) in the closure cap stack bears with its convex outer face on the concave inner face of a lower closure cap (10) lying immediately below in the closure cap stack, iv. a closure gripper (20) for gripping an uppermost closure cap (10) from the at least one closure cap stack, for transferring the gripped closure cap (10) to the sample vessel (PG) to be closed, and for introducing the gripped closure cap (10) into an opening of the sample vessel in order to tightly close the opening, wherein the closure gripper (20) has a centering piece which can be inserted into a closure cap (10) in such a way that it bears on the concave inner face of the closure cap (10). With such a system, automated closure of sample vessels is possible in a space-saving and efficient way. Furthermore, a method for automatic closure of sample vessels is also disclosed.

This utility model released one kind of multifunctional flexibly transformable cup, comprising one internally cut-through transformable cup and a nested bottom plug that is sealed and clamped with the transformable cup body. The above-mentioned transformable cup is comprised of a foldable enclosure and pin that are successively cut-through and flexibly and tightly connected. The aforesaid seal clamp for embedded bottom plug is located at the junction between the foldable enclosure and pin. When the multifunctional flexibly transformable cup of the utility model is in use, the folding enclosure body can be overturned freely, and the whole body is made of food-grade flexible silica gel material, which is safe and reliable and not easy to be broken. It can also be used as the wine cup, bottle stopper and the bottleneck inserted into the wine bottle that can be directly used for drainage of fluid, with complete functions.

This utility model released one kind of multifunctional flexibly transformable cup, comprising one internally cut-through transformable cup and a nested bottom plug that is sealed and clamped with the transformable cup body. The above-mentioned transformable cup is comprised of a foldable enclosure and pin that are successively cut-through and flexibly and tightly connected. The aforesaid seal clamp for embedded bottom plug is located at the junction between the foldable enclosure and pin. When the multifunctional flexibly transformable cup of the utility model is in use, the folding enclosure body can be overturned freely, and the whole body is made of food-grade flexible silica gel material, which is safe and reliable and not easy to be broken. It can also be used as the wine cup, bottle stopper and the bottleneck inserted into the wine bottle that can be directly used for drainage of fluid, with complete functions.

The present invention relates generally to a container that may be sealed and reclosed with a threaded closure. More specifically, the present invention relates to methods of manufacturing a metallic container having an opening with inwardly facing threads that are formed after a threaded closure is inserted at least partially into the opening. The container opening may be selectively sealed and reclosed with the threaded closure which releasably engages the container threads.

A system and method for automatic closure of sample vessels such as vessels with medical laboratory samples, having a plurality of identically shaped, stackable closure caps with a convex outer face and concave inner face that are stacked in a closure cap stack such that an upper closure cap in the stack bears with its convex outer face on the concave inner face of a lower closure cap lying immediately below in the stack. The system includes a closure gripper for gripping an uppermost closure cap from the stack, for transferring the gripped closure cap to the sample vessel to be closed, and for introducing the gripped closure cap into an opening of the sample vessel in order to tightly close the opening. The closure gripper has a centering piece insertable into a closure cap such that it bears on the concave inner face of the closure cap.