A sampling device and associated methods for collecting a plurality of samples of a solution in a medical sterilization device. The sampling device includes a base configured to support a plurality of vessels, and a cover. The cover and the vessels define an orientation in relation to each other with the orientation having a first position permitting ingress of the solution into a first vessel and preventing ingress of the solution into the second vessel, a second position permitting ingress of the solution into a second vessel and preventing ingress of the solution into the first vessel. The sampling device may alternatively comprise a plurality of covers each coupled to one of the vessels. Actuators may move the covers between configurations permitting and preventing ingress of the solution into the vessels. Control of the covers may be based on analytical characteristics measured in by a sensor within a flow path.

The disclosure relates to a sampling system for processing a liquid sample, including a retrieving module configured to be fluidically connected to a liquid-source and configured to retrieve a liquid sample from the liquid-source, a filling module configured to fill the retrieved liquid sample into a sampling container, a storing module configured to store the sampling container filled with the liquid sample, and a disposal module configured to discard the liquid sample.

A milking system includes a milking device, a milk line, and a sampling and analysis device for the milk that includes a control unit, a tape mover to move and unwind a tape wound on a tape reel and with a base material with reagent pads, that detect a substance in the sample, and a dosing device to provide the sample onto a reagent pad, and a sensor to detect radiation from said reagent pad, and to analyse the detected radiation to indicate a presence or concentration of said substance. The reagent pad is facing downward during provision of the sample. In this way, the chance of excess liquid falling from the reagent, and possibly onto a camera, is reduced. Smaller reagent pads may be used, it reduces the chance of supplied liquid spilling over to a neighbouring reagent pad, the measures preventing this spilling may be limited, and it is easier to suck away excess fluid.

The disclosure relates to a sampling system for processing a liquid sample, including a retrieving module configured to be fluidically connected to a liquid-source and configured to retrieve a liquid sample from the liquid-source, a filling module configured to fill the retrieved liquid sample into a sampling container, a storing module configured to store the sampling container filled with the liquid sample, and a disposal module configured to discard the liquid sample.

A soil probe assembly includes a frame member and a wheel rotatably coupled to the frame member. The wheel includes one or more soil probes that, as the wheel rotates against the earth, the weight of the soil probe assembly drives the soil probes into the earth. The wheel is configured to have at least two planar edges such that, as the wheel rolls onto one of the at least two planar edges, a slamming effect occurs due to the planar edge impacting against the ground, thus causing a soil sample to eject from a soil probe located across the wheel from the ground. The ejected soil sample is collected by a collection hamper. The assembly includes a funnel and a carousel such that the funnel is configured to receive and direct the ejected soil sample to the collection hamper, wherein the collection hamper is coupled to the carousel.

Embodiments of the invention collect solid, vapor, and/or biological components of the air in air-sampling cartridges that are then transported to an off-site location by pneumatic pressure. Operation proceeds by first collecting a sample of air in an air-sampling cartridge in a sampling position, then advancing a cartridge assembly to move the now-used sampling cartridge into a transport position while simultaneously moving an unused sampling cartridge into the sampling position, and finally using pneumatic pressure to push the used sampling cartridge in the transport position to an off-site location via a transport tube. The sampling operation can begin again while the transport operation is in still in progress. These operations can be pre-programmed locally or triggered by remote communication. Continued operation is possible due to a plurality of unused air-sampling cartridges retained in the cartridge assembly. Since operations can be triggered remotely and air samples are autonomously transported off site, embodiments of this invention eliminate unnecessary risks to human health created by other air-sampling devices, which require an operator to be present at a potentially hazardous sampling site to activate the device or retrieve air samples. Additionally, embodiments of the invention can be installed preemptively to eliminate risks to human health created when an operator must deliver a portable air-sampling device to a potentially contaminated sampling site. Furthermore, embodiments of the invention allow rapid retrieval of air samples following sample collection, which can expedite analysis and identification of aerosols and consequently help minimize human exposure to potentially dangerous and life-threatening chemical and biological contaminants.

A milking system includes a milking device, a milk line for carrying milk, and a sampling unit arranged to take a sample from the milk line and test the sample for the presence or concentration of at least one substance. The sampling unit is provided with a housing. The housing includes a supply reel with a tape that carries reagent, and a sample supplier. The sampling unit includes a tape displacer displacing the tape, a sample analyser, and a used tape collector device collecting tape with reagent to which a sample has been supplied. The supply reel at a surface thereof includes a desiccant, or is completely made of a desiccant material. This provides such a large volume of desiccant that the correspondingly high moisture absorption capacity ensures an uninterrupted useful life of the sampling unit, and thus of the milking system.

Embodiments of the invention can sample particulates, aerosols, vapors, and/or biological components of ambient air utilizing spherical air-sampling filters. Components of the embodiments may include a hopper for holding spherical air-sampling filters, an air-sampling manifold configured to deliver an air-sampling filter from the hopper to a sampling location, and an air compressor to perform an air sampling operation and to transport a used air-sampling filter away from the sampling location. Operation of some embodiments may begin by rotating a slotted drum within the air-sampling manifold to deliver an air-sampling filter from the hopper to the sampling position. Operation may continue by using the air compressor to draw air from an ambient environment through the air-sampling filter. After sampling is complete, the air compressor may be utilized to pneumatically transport the used air-sampling filter away from the sampling position to a filter retrieval location via an output tube.

An automatic slicing and collecting device, the device including: a first tank, a vibrating microtome, a first pipeline, and a second pipeline. The first tank is filled with a buffer solution. The vibrating microtome is disposed in the first tank. One end of the first pipeline is connected to the vibrating microtome to collect sections, and the other end of the first pipeline is connected to a pump. The pump includes a reversible motor. The first pipeline is provided with a first valve, and a filter is disposed between the pump and the first pipeline. One end of the second pipeline is disposed between the first valve of the first pipeline and the pump, and the second pipeline is provided with a second valve.

Embodiments of the invention collect solid, vapor, and/or biological components of the air in air-sampling cartridges that are then transported to an off-site location by pneumatic pressure. Operation proceeds by first collecting a sample of air in an air-sampling cartridge in a sampling position, then advancing a cartridge assembly to move the now-used sampling cartridge into a transport position while simultaneously moving an unused sampling cartridge into the sampling position, and finally using pneumatic pressure to push the used sampling cartridge in the transport position to an off-site location via a transport tube. The sampling operation can begin again while the transport operation is in still in progress. These operations can be pre-programmed locally or triggered by remote communication. Continued operation is possible due to a plurality of unused air-sampling cartridges retained in the cartridge assembly. Since operations can be triggered remotely and air samples are autonomously transported off site, embodiments of this invention eliminate unnecessary risks to human health created by other air-sampling devices, which require an operator to be present at a potentially hazardous sampling site to activate the device or retrieve air samples. Additionally, embodiments of the invention can be installed pre-emptively to eliminate risks to human health created when an operator must deliver a portable air-sampling device to a potentially contaminated sampling site. Furthermore, embodiments of the invention allow rapid retrieval of air samples following sample collection, which can expedite analysis and identification of aerosols and consequently help minimize human exposure to potentially dangerous and life-threatening chemical and biological contaminants.