Abstract: A fired cartridge case collector includes a base having a collection post. The collection post of the base is configured to collect and suspend a fired cartridge case without causing contact to an exterior surface of the fired cartridge case. The fired cartridge case collector also includes a protective envelope having a first end and a second end opposite the first end, wherein the first end of the protective envelope is configured to be removably secured to the base. The protective envelope is configured to prevent contact between an interior surface of the protective envelope and the exterior surface of the fired cartridge case while the protective envelope is removably secured to the base. The fired cartridge case collector permits individual collection, packaging, and non-contact storage of fired gun cartridge cases thereby preserving any DNA or other evidence that may be present.

Abstract: Disclosed herein is a bioreactor system that allows perfusive flow through a porous support medium enabling 3D growth of biological samples. In some embodiments, the system comprises a sample well filled with a three-dimensional (3D) cell growth medium. The system can further comprises a liquid medium reservoir fluidly connected to the sample well by a first filter material. The system can further comprises a medium collection chamber fluidly connected to the sample well by a second filter material. The system can further comprise an absorbant material that creates an osmotic pressure gradient to produce perfusive flow. In some embodiments, osmotic pressure draws fluid from the liquid medium reservoir, through the first filter material, into the sample well where it permeates the three-dimensional cell growth medium, through the second filter material, and finally into the medium collection chamber.

Abstract: A bioreactor vessel includes a bottom plate, a vessel body coupled to the bottom plate, the vessel body and the bottom plate defining an interior compartment therebetween, and a plurality of recesses formed in the bottom plate, each recess of the plurality of recesses being configured to receive a corresponding alignment pin on a bed plate for aligning the bioreactor vessel on the bed plate.

Abstract: A system for mixing solutions includes: a first container and at least one second container capable of containing solutions, each second container being capable of entirely containing the first container; means for displacing the first container and/or each second container capable of entirely immersing the first container in each second container; and rotational drive means for the first container so as to mix the solutions present in the first and second containers when the first container is entirely immersed in the solution present in the second container.

Abstract: A feces sampling container includes: a lid (2) that includes a feces sampling rod (2b) and a cap (2a), a circular protrusion (2f); a container body (3); and an inside plug (4) that includes a removal part (4b), and a circular protrusion (4g), the inside plug (4) being fitted to the inside of the container body (3), a flange (3c), an overhang (4d) being formed on the outer circumferential surface of the inside plug (4) at a predetermined position along the circumferential direction so that the overhang (4d) is situated on the flange (3c), a removal mechanism (2e, 4f), and a cam mechanism (2h, 4h) that positions the removal mechanism being formed over the circular protrusion (2f) formed on the inner circumferential surface of the cap (2a) and the circular protrusion (4g) formed on the outer circumferential surface of the inside plug (4).

Abstract: Provided is a weighted anchor for a tape measure. The device includes a tubular housing with a defined interior volume for holding one or more magnetic weights therein. The weights are positioned around an elevator bolt disposed within the interior volume, then secured within the interior volume via a washer and a bolt. In this way, the weights are arranged in a stacked orientation. The housing can be secured to an end of a standard tape measure, thereby weighing down the same. In this way, the present invention can prevent the tape measure from swinging or otherwise oscillating when measuring long distances.

Abstract: A system for preparing samples for chemical analysis comprises at least one sample container, and a container receptacle apparatus for receiving the sample container. The sample container comprises an elongate tubular body having a crucible portion proximal to a closed end for receiving a sample therein, and an expansion portion proximal to an open end. The container receptacle apparatus comprising a housing having a heating compartment, a cooling compartment spaced apart from the heating compartment, and an insulating region located between the heating compartment and the cooling compartment. The heating compartment is shaped to receive the crucible portion of the sample container, and the cooling compartment is shaped to receive the expansion portion of the sample container. The apparatus also includes a heating mechanism for heating the sample within the crucible portion of the sample container, and a cooling mechanism for cooling the expansion portion of the sample container.

Abstract: A soil sampling apparatus comprising a motorized vehicle may be used to remove soil samples at intervals over a field of interest. The apparatus comprises a sampling assembly that rotates and extends downwardly into the soil to collect a sample. The probe assembly is raised to dump the sample into a collection assembly, which transfers the sample to a bagging assembly, where the sample may be bagged for later analysis.

Abstract: In a device for taking samples from a material flow of fine-grained and dry material, in particular in the cement industry, comprising an upwardly open sample chamber (2) capable of being introduced into, and retracted from, the material flow through an introduction socket, the sample chamber (2) is formed in a rod-shaped body (1) translationally guided between a sampling position and a retracted position, and the sample chamber (2) has an openable bottom (7).

Abstract: The composition for coating of a surface intended to be exposed to a metal melt is disclosed. The composition essentially consists of: 8-18 wt-% of a refractory component; 50-75 wt-% of solvent, preferably water; 10-20 wt-% of an inorganic binder; 0-10 wt-%, preferably 2-10 wt-%, of an organic binder; 0.3-7 wt-%, preferably 2-6 wt-%, more preferably, 3-5 wt-% of pyrite; and optionally up to 10 wt-%, preferably up to 5 wt-%, of additional additive or additives. The composition results in a coating on a surface, which coating is able to reduce the dissolved elemental magnesium content in a metal melt to which the surface is exposed.

Abstract: A sampling device comprises a container having an essential cylindrical part and a bottom part. The container further comprises an inner wall member and an outer wall member. The inner wall member and the outer wall member are essentially coaxially arranged in the cylindrical part of the container and joined at the top part of the container, and the inner and outer wall members define a closed insulating space between the outer surface of the inner wall member and the inner surface of the outer wall member. The sampling device further comprises temperature responsive means adapted to extend into the sample quantity during thermal analysis. Spacer means is arranged in the insulating space in the bottom part of the container and/or in the cylindrical part of the container in the vicinity of the bottom part.

Abstract: The present invention discloses a device as well as a collection element (1) for collecting a chemical and/or biological sample directly from a surface exposing said sample material. Furthermore, a method for collecting a chemical and/or biological sample directly from a surface exposing said sample material and a kit thereof is subject-matter of the present invention.

Abstract: A moveable end (ME) sample cylinder device is provided which employs a method of collection wherein the initial cylinder volume of the collection vessel or sampling cylinder is zero. The sample cylinder is inserted into the pressurized gas (or fluid) source for spot sampling thereof, said sample cylinder employing a piston or moveable end configured such that purging of the cylinder sample cavity is not required, since the sample cavity volume is essentially eliminated prior to sampling by the location of the piston within the cavity, the cavity expanding upon sampling via piston movement within the cavity. Also contemplated is a cap/body (CB) spot sample cylinder having a low internal volume and which can be inserted into a pressurized process through common valving. Insertion of the CB sample cylinder into the process eliminates purging of interconnecting tubing and also eliminates the impact of low ambient temperatures which can otherwise alter the spot sample composition.

Abstract: The disclosure is directed to a device for fluid sampling. The device may have two panels that are or may be adhered, attached or otherwise connected to opposite sides of a sampling bag having flexible walls. The panels may be used for conveniently inflating or deflating the sampling bag and obtaining fluid samples.

Abstract: A method is provided for analyzing samples of metal melts, wherein a sample is taken from a metal melt using a sampler having a sample chamber and which is constructed as an immersion lance. The method includes transporting the sample from the sampler through a transport conduit to the sphere of action of an analytical device, and analyzing the sample there using the analytical device.

Abstract: An immersion probe for analysis of gases in molten metal is provided. The immersion probe generally comprises a gas sampler, a gas injection tube and a porous ceramic filter. The porous ceramic filter has a groove that associates it to the gas sampler, the groove comprising an outer portion and an inner portion with respect to the gas sampler, the inner portion of the porous ceramic filter having an increase in body for better association of the porous ceramic filter to the gas sampler. An adhesive material provides mechanical support of the porous ceramic filter, the adhesive material being located in both the inner portion and the outer portion of the gas sampler.

Abstract: The present invention describes a tubular scoop that may be utilized with various assemblies for sampling fluid in a pipeline. The scoop includes a bend with a bend radius that is from two to four times the diameter of the scoop. The scoop defines a scoop face that is parallel to an axis of the tubular of the scoop. The scoop is mounted with a threaded connection that seals around the tubular. An additional seal comprises a compression nut that allows orientation of the scoop within the pipeline whereupon the scoop orientation is fixed by tightening the compression nut.

Abstract: Sample processing units useful for mixing and purifying materials, such as fluidic materials are provided. A sample processing unit typically includes a container configured to contain a sample comprising magnetically responsive particles, and one or more magnets that are in substantially fixed positions relative to the container. A sample processing unit also generally includes a conveyance mechanism configured to convey the container to and from a position that is within magnetic communication with the magnet, e.g., such that magnetically responsive particles with captured analytes can be retained within the container when other materials are added to and/or removed from the container. Further, a sample processing unit also typically includes a rotational mechanism that is configured to rotate the container, e.g., to effect mixing of sample materials disposed within the container. Related carrier mechanisms, sample processing stations, systems, and methods are also provided.

Abstract: An apparatus for collecting fragments from a substrate subjected to an exploded munition, including a predetection element for removing large fragments from a sheet of the substrate; a detection and removal element for locating fragments embedded within the sheet and for removing located fragments from the sheet; and a capture element for capturing removed fragments.

Abstract: The invention provides a liquid storage installation which includes a tank (70) containing a liquid and a device (10) for measuring and sampling the liquid. The device (10) includes an elongate hollow body (12) having a closed bottom and a plurality of spaced apart sampling ports (20, 22, 24) at spaced apart positions. The device (10) further includes a sleeve (14) which extends around the sampling port and in which corresponding sampling ports (26, 28, 30) are provided at spaced apart positions. The body (12) and sleeve (14) are displaceable relative to one another between an open position in which the sampling ports are in register permitting liquid flow between the tank and the interior of the body and a closed position in which the ports are out of register and flow between the tank and the interior of the body (12) is prohibited.

Abstract: A scent storage element is described. The scent storage element includes: a scent-retaining portion formed by at least one sealed section along an edge of the scent storage element; a re-sealable feature along an edge of the scent-retaining portion; and a tamper-proof element adapted to provide an indication as to whether the re-sealable feature has been opened after the tamper-proof element has been secured. A scent collection and storage kit includes: a case; a scent storage element; a scent retention element adapted to fit within the scent storage element; and usage instructions. A scent collection kit includes: a scent retention element; and a scent storage element adapted to house the scent retention element.

Abstract: A method, apparatus and system for obtaining a sample of a fluid solids, such as a coke and hydrocarbon mixture, from a fluid solids process is provided. A sample vessel is provided that contains a first end, a second end, an aperture in the first end and an interior cavity. A cooling device can be provided for cooling material in the interior cavity of the sampling vessel. In operation, fluid solids can be routed through the aperture and collected in the interior cavity. The collected sample material can then be cooled by the cooling device and used for testing.

Abstract: Provided are methods for detecting a cancer, such as an ovarian cancer. In certain aspects, the methods involve detecting or measuring one or more volatile organic compounds (VOCs) from the breath of a subject. Apparatuses for the collection of VOCs are provided.

Abstract: The disclosure is directed to a device for fluid sampling. The device may have two panels that are or may be adhered, attached or otherwise connected to opposite sides of a sampling bag having flexible walls. The panels may be used for conveniently inflating or deflating the sampling bag and obtaining fluid samples.

Abstract: The invention relates to a device for collecting samples from a powder stream guided in a powder line (3). The device comprises a housing (1) that is disposed on the powder line (3), a slide (5) which comprises a sample well (13) disposed upwardly relative to the powder stream, and a pushing device. There is a sample container (18) provided that matches the sample well (13). An associated withdrawal device (19) comprising withdrawal tongs (20) can be inserted into the housing (1) in such a way that the withdrawal tongs (20) are located axially above the sample well (13) in the inoperative position of the slide (5) and can be fitted on the sample container (18) and connected to the same.

Abstract: A gas sampler device has a top plate with a concaved outer wall. The concaved outer wall allows users easily to lift the top plate off of the bottom plate without disturbing the bottom plate because the curved surface permits more positive contact between the outer wall and users' fingers. Moreover, the weight of the top plate is reduced by approximately twenty percent compared to conventional top plates, a feature that also makes it easier for users to lift the top plate off of the bottom plate.

Abstract: An apparatus and a method for online sampling from a product flow, where the sampling is performed continuously by introducing a cup, provided with an opening, directly into a product flow where the flowing product is collected in the cup for determining one or more physical conditions, for example, weight in relation to volume, moisture, size and/or color. The apparatus has at least a slidable cup and a device for sliding the cup. The apparatus also has a filter element and a device by which the filter element is brought into position in relation to an opening in the cup, an aerator for aeration of the sample taken in the cup, and at least a set of sensors for determining the presence of contents and/or physical conditions of the contents in the cup.

Abstract: It is to provide a device for sampling feces that enables an accurate and quantitative evaluation by decreasing the variations of feces sampling levels, wherein the confirmation of the presence or absence of feces sampling can be performed hygienically and simply from an outside of a container.

Abstract: An apparatus for collecting fragments from a substrate subjected to an exploded munition, including a predetection element for removing large fragments from a sheet of the substrate; a detection and removal element for locating fragments embedded within the sheet and for removing located fragments from the sheet; and a capture element for capturing removed fragments.

Abstract: A transport container system for a water analysis sensor cartridge includes a water analysis sensor cartridge configured to be interchangeable. The water analysis sensor cartridge comprises at least two different sensor membranes. A transport container cup comprises, for each of the at least two different sensor membranes, a separate moist chamber. Each separate moist chamber comprises one chamber opening and a specific humectant for each of the at least two different sensor membranes.

Abstract: A container for collecting a biological specimen is provided that includes a peripheral wall extending from a base. The container further includes a longitudinal tower disposed within the container. The tower forms a partition within the container to form at least a first chamber and a second chamber therein, wherein the first and second chambers are in fluid communication with one another. In addition, the container include an insert disposed within the container opposite the base, the insert comprising at least a first opening and a second opening. The second opening provides access to the second chamber and is further configured to engage a specimen collecting device to leave a portion of the specimen collecting device within the second chamber. The first opening provides access to the first chamber and is further configured to receive a syringe therein for accessing the biological specimen. Associated systems and methods are also provided.

Abstract: The present invention refers to the subsampler and to a subsampling method that allows for the execution of environmental monitoring without the use of large sample volumes, thus ensuring specimen wealth and expedited analyses.

Abstract: A device is provided for measuring parameters or for taking samples in molten iron or steel and for taking samples of slag resting on the melt. The device includes a carrier tube having an immersion end, a lateral circumferential surface, and a measuring head arranged on the immersion end. At least one sensor or inlet opening for a sample chamber present inside the device is arranged at the immersion end of the measuring head. The lateral circumferential surface of the carrier tube or measuring head has an inlet opening extending through an inlet channel to merge in a pre-chamber arranged inside the carrier tube or measuring head. The pre-chamber has, at its end facing away from the immersion end, an entry opening that merges into a slag sample chamber on the side of the pre-chamber facing away from the immersion end.

Abstract: A cup assembly for holding a sample to be analyzed spectrochemically, includes a tubular longitudinal member which is disposed symmetrical about a central axis. The tubular member extends longitudinally between a first end and a second end. An indented peripheral flange is defined at the second end. The indented flange has an inverted L shaped cross-section. An annular collar extends longitudinally between a first end and a second end. An internal peripheral flange is defined at the first end. The internal flange has an inverted L shaped cross-section complementing the indented flange of the tubular member. When a substantially thin film is interposed between the second end of the tubular member and the first end of the annular collar, the film is retained between the sample cell body and the collar between the indented flange and the internal flange. The cup may have a funnel shaped sample retaining chamber.

Abstract: A collection unit (80) of this invention includes: a collection carrier cartridge (82) formed, at its center, with a through hole (82b3) into which a nozzle for supplying hot water or ATP reagent is inserted including a carrier filling dish (82b), on an outer circumference of the through hole (82b3), to be filled with a collection carrier (90) for collecting floating bacteria in the air and an upper lid (82a) on which the carrier filling dish (82b) is placed, formed with a protrusion to be inserted through the through hole (82b3); an impactor nozzle head (86) which covers a surface of the collection carrier (90) and has a plurality of nozzle holes (87) facing the surface of the collection carrier (90); and a fan (84) which introduces air to the surface of the collection carrier through the nozzle holes (87). A velocity of the air passing through the nozzle holes (87) is 40 m/s to 50 m/s.

Abstract: The invention relates to an accessory for a drilling apparatus for drilling holes into the ground and into which explosives can be filled for blasting purposes. Such drilling commonly occurs in open cast mining for mining of mineral deposits. It is known to take samples from materials blown from holes during drilling, permitting analysis of the samples in order to estimate accurately the mineral content in the area being mined. The accessory is operatively supported on a drilling apparatus and includes a dust particle catcher, for catching dust particles blown from a hole to form dust particle samples, and a collection arrangement including receptacles in which dust particle samples are collected. A control arrangement of the accessory controls the operation thereof and serves also to enable the hole and the depth region of the hole, from which each sample was collected, to be identified.

Abstract: There is provided a sample collection container, a sample collection apparatus, and a sample collection method used in a supercritical fluid system capable of collecting a multi-constituent sample contained in a supercritical fluid at low cost and high collection efficiency. The pressure of a supercritical fluid containing a sample is reduced to a pressure close to the atmospheric pressure, and the depressurized supercritical fluid is forced to undergo adiabatic expansion to form gas-phase CO2 containing a liquid component in the form of aerosol. The gas-phase CO2 is fractionated for each constituent of the contained sample, transferred to a probe 60 of Liquid Handler, and dispensed into a large number of collection vials 300 under the atmospheric pressure, each of which is provided with a vial cap 100.

Abstract: A liquid testing assembly for testing a liquid, the assembly comprising a test vessel and a stopper adapted to fit into a free end of the vessel. The stopper substantially hermetically seals the test vessel from the ambient. Further, the assembly includes a support coated with one or more identifying materials for identifying one or more constituents of the liquid. The support is fixed in the stopper and/or the vessel and extends into its interior for a predetermined distance. The liquid testing assembly when assembled is pre-evacuated to a predetermined vacuum sufficient to draw a predetermined volume of liquid to be sampled into the test vessel. The predetermined volume is of such an amount that it wets the one or more identifying materials ensuring identification of one or more constituents present in the liquid. A kit employing the liquid testing assembly is also discussed.

Abstract: A sample collecting device including an outer casing and a valve assembly disposed at least partially within the outer casing and configured to obtain a sample of a sample material. A method of sampling sediment including entering a sample collecting device into a fluid storage container, contacting a surface of a sample material with the sample collecting device, obtaining a sample of the sample material, and removing the sample collecting device from the fluid storage container.

Abstract: The present invention relates to a device (20) for collecting dialysate samples (42). The device (20) comprises an inlet (22) for receiving a flow of dialysate, a plurality of outlets (24) for providing a flow of saturated dialysate and means (26) for sequential selection of one of the outlets (24). The sequential selection means (26) are activated only by the flow of dialysate received from the inlet (22). The present invention further relates to a system for peritoneal dialysis comprising such device (20).

Abstract: The invention relates to a device for collecting samples from a powder stream guided in a powder line (3). The device comprises a housing (1) that is disposed on the powder line (3), a slide (5) which comprises a sample well (13) disposed upwardly relative to the powder stream, and a pushing device. There is a sample container (18) provided that matches the sample well (13). An associated withdrawal device (19) comprising withdrawal tongs (20) can be inserted into the housing (1) in such a way that the withdrawal tongs (20) are located axially above the sample well (13) in the inoperative position of the slide (5) and can be fitted on the sample container (18) and connected to the same.

Abstract: The present invention relates to a sampler for gas hydrates by hole bottom freezing, the sampler comprises a fisher, a wire-line coring mechanism and an outer barrel, and it further comprises a refrigeration portion, a low temperature control portion and a frozen insulation sample portion, which constitute an inner barrel assembly located inside the outer barrel together, wherein a refrigerant in the refrigeration portion is injected into the frozen insulation sample portion under a control of the low temperature control portion, so that a cooling medium in the frozen insulation sample portion is always kept under a predetermined temperature, and a core sample of gas hydrates is frozen at the bottom of a drill hole. The invention also relates to a sampling method using the sampler as mentioned above.

Abstract: A method is provided which is capable of efficiently taking most of a precious sample into an extraction vessel without wasting when the sample is extracted from a collection section of a sampling rod. The method includes the steps of collecting a sample using a sampling rod formed of a rod body and a collection section attached to the rod body, inserting the sampling rod into the extraction vessel, placing the rod body in a gap formed in a grappling hook section which is disposed in an insertion path of the sampling rod, the gap having a width smaller than a diameter of the collection section and being capable of receiving the rod body, withdrawing the rod body with the rod body being placed in the gap and detaching the collection section from the rod body by hooking the collection section to the grappling hook section.

Abstract: The present invention is directed to containers for fluids. The containers may comprise a flexible wall, wherein the flexible wall comprises a metal alloy. The metal alloy may be any metal alloy that may be formed into a sheet including, but not limited to, some stainless steel alloys such as SST 304, SST 309, SST 316, SST 316L, SST 321, low carbon stainless steels and nickel-titanium alloys known as Nitinol.

Abstract: The disclosure is directed to a device for fluid sampling. The device may have two panels that are or may be adhered, attached or otherwise connected to opposite sides of a sampling bag having flexible walls. The panels may be used for conveniently inflating or deflating the sampling bag and obtaining fluid samples.

Abstract: A F.O.G. water sampling apparatus includes a housing having an inlet, an outlet, a floor that slopes downward from the inlet to the outlet and an open top. A first insert placed in the housing for normal operation includes a pipe having end flanges making a friction fit within the housing and connecting the inlet and outlet and spanning above the housing floor. A second, substitute insert to receive a F.O.G. sampling jar has a floor that slopes downward from the inlet to the outlet and at the floor of the housing.

Abstract: Device for collection and stabilization of biomarkers in liquid samples. In at least one embodiment of a fluid collection device, the device comprises a housing having a top end, a bottom end, and a tubular compartment therethrough, a swab connected to bottom end of the housing and in fluid communication with the tubular compartment, the swab designed to collect a body fluid, and a stabilizing agent contained within the fluid collection device, the stabilizing agent capable of completely or substantially preventing the degradation or inactivation of a diagnostic agent in a bodily fluid upon receipt of the bodily fluid into the fluid collection device. Optionally, the stabilizing agent may be coupled to the swab, and/or contained within the tubular compartment of the housing.

Abstract: A container for specimen of the present invention comprises: a container body one end of which is open and which can hold a liquid for dispersing or preserving a specimen and can be mounted in a general-purpose apparatus for physical and chemical analysis; a specimen-picking rod; a cover member which connects with the specimen-picking rod; and an intermediary unit. The both ends of the intermediary unit are open, and the intermediary unit includes a penetration wall in the middle portion of the intermediary unit. The one open end of the intermediary unit can be removably fit to the open end of the container body, and the other open end of the intermediary unit can be removably fit to the cover member. The penetration wall separates a space in the intermediary unit into two divisions on the upper and lower sides in the state of the specimen-picking rod penetrating through a through hole that is formed in the penetration wall.

Abstract: Apparatus is provided for determining presence of contamination on a lithography mask, including: a fluid trap having a base and at least one wall member extending substantially perpendicularly to the base for trapping fluid on a portion of the base when fluid introduced during a cleaning process of the mask is removed.

Abstract: A hollow container defining a sample chamber is formed of at least two parts which fit together and have apertures therein. One of the parts is displaceable relative to the other part between a first relative disposition of the parts in which the apertures are open so as to provide a clear path for air to pass through the container and a second relative disposition of the parts in which the apertures are closed so that there is no path for air to pass through and a volume of air is trapped in the chamber. In one embodiment part is axially moveable relative to the other part. In another embodiment where the parts are tubular, one of the parts is rotatable relative to the other.