The present disclosure relates to a portable device for collecting and/or concentrating in situ plankton microbiome, configured for submersion in water. The device herein disclosed is a compact and low-cost autonomous biosampler, with the ability to yield DNA samples for later genomic analysis.

Methods, apparatus, and systems are provided for detecting and removing microplastics from wastewater effluent. Both, automatic/remote and manual monitoring and sampling components are included to detect the presence of microplastics. The automatic monitoring and sampling component includes a TSS sensor and associated apparatus calibrated to account for non-plastic solids present in the wastewater and, thereby, more accurately determine the presence of microplastics. Efficient separation and removal of microplastics from wastewater effluent is performed by a specialized capture net apparatus having multiple sized mesh components and optional diffuser devices which perform size exclusion filtration of microplastics from the water. In an exemplary embodiment, the methods generally include diverting treated wastewater effluent from a wastewater treatment facility's main line into a wastewater sampling mechanism via an intake pipe, and then into a solids monitoring and separation mechanism which includes the specialized capture net apparatus.

The test device is provided with a testing means for testing an added extraction solution utilizing immunochromatography or nucleic acid chromatography, an extraction solution container, and a tubular guiding member having an extraction solution inflow port communicating with the extraction container in a sealed manner at one end side and having an extraction solution outflow port at the other end side. The guiding member is configured so as to have inside the tube a rod-shaped extraction solution guide having capillary action and having one end at the extraction solution outflow port side able to contact the testing means and so that the extraction solution absorbed from the extraction solution inflow port side at the extraction solution guide moves by capillary action through the inside of the extraction solution guide and is added to the testing means through the one end of the extraction solution guide contacting the testing means.

In one embodiment, a sample probe has a cap and a base, wherein the cap includes a grip portion and a projection portion. The projection portion fits within a hollow portion of a filter such that the filter is disposed on the outside of the projection portion and the filter and the cap form a cap assemblage. The base comprises a base recess that receives a portion of the cap assemblage including the filter. The cap and base include corresponding media transfer regions adjacent and connected to the filter that reduces flow resistance and chances of blockage and/or contamination during dissolution-testing sampling using the sample probe.

A laser module includes a plurality of light emission regions and the plurality of light emission regions emit a plurality of laser beams. An optical waveguide and a lens condense the plurality of laser beams to an identical focal point. An adjustment mechanism is configured to adjust relative positional relation between the sample stage and a condenser lens (the optical waveguide and the lens). A controller is configured to switch between a single-point irradiation mode and a multi-point irradiation mode. The single-point irradiation mode refers to a mode in which the adjustment mechanism is controlled such that the focal point of the plurality of laser beams falls on the thin film. The multi-point irradiation mode refers to a mode in which the adjustment mechanism is controlled such that the focal point does not fall on the thin film.

The present invention provides a device (1) for detecting contamination with a photosynthesis inhibitor, the device including a collection device (10) configured to collect a test liquid, a light-blocking pretreatment tank (21) configured to store the test liquid (2) collected by the collection device in a state of containing phytoplankton, a stirring device configured to maintain a floating state of the phytoplankton in the test liquid stored in the pretreatment tank, an irradiation light source configured to irradiate the phytoplankton in the test liquid stored in the pretreatment tank with weak light having an underwater photon flux density that does not cause photoinhibition, a drainage conduit (40) configured to allow the test liquid discharged from the pretreatment tank to flow thereinto, and a fluorescence quantum efficiency measuring machine (50) provided for the drainage conduit and configured to measure a fluorescence quantum efficiency of the phytoplankton in the test liquid discharged from the pretreatment tank, and a method for detecting contamination with a photosynthesis inhibitor, the method including a liquid supply step, a storing and weak-light irradiation step, and a fluorescence quantum efficiency measurement step.

A trap for marine sediments, comprising on two vertical sides, opposite to each other, a first inlet opening and a second outlet opening, configured to allow the inlet and the outlet of the marine current, the trap comprising between said two openings an inlet area, whose section diverges in terms of width between said inlet opening and the end section of the inlet area; a sedimentation area having a section greater than the end section of the inlet area, configured to allow the separation by gravity of the particles present in the marine current, and an outlet area whose section converges in terms of width between the section where the outlet area is connected to the sedimentation area and the second outlet opening having the section of the inlet area converges in terms of height between the inlet opening and its own end section.

A long-term in-situ observation device for the deep sea bottom supported engineering geological environment is provided, including: a sediment acoustic probe, a sediment pore water pressure probe, a three-dimensional resistivity probe, a water observation instrument, a long-term observation power supply system, a probe hydraulic penetration system, a general control and data storage transmission system, an acoustic releaser, an underwater acoustic communication apparatus, and an instrument platform. The observations include the engineering properties, physical properties, mechanical properties, and biochemical properties of a seawater-seabed interface-sediment. The engineering properties and the physical and mechanical indexes of seafloor sediments are comprehensively determined by three-dimensional measurement of seafloor resistivity and acoustic wave measurements. The physical and biochemical properties of seawater are expected to be acquired by sensors. The observation probe penetrates into the sediments following the hydraulic method. Powered by seawater dissolved oxygen batteries; data transmission is achieved through sea surface relay buoys and satellite communications. The present invention provides an effective integrated, in situ and long-term observation device and method for the deep sea engineering geological environment.

A sampling device includes a pig-retaining pipe, a plurality of pipes extensions, a plurality of pipe couplings, a winch and support jig, a sample spout, a bottom cap, a pig, and a cable. A storage tank holds product-fuel, water, sludge, and a hard volume. The sampling device is used to collect and sample contents of the storage tank. The sampling device is assembled with the pig attached to a bottom cap coupled to the pig-retaining pipe. The sampling device is inserted into the storage tank to the desired depth. Contents of the storage tank enter into the sampling device through openings in the pig-retaining pipe. The winch is used to pull the cable upwards and draw the pig up through the sampling device. As the pig is pulled upwards, contents exit through the sample spout. The contents are stored in a container that is sent to a laboratory for analysis.

The present application discloses a grouting consolidation sample containing internal defects and the preparation method thereof. Firstly, plasticine is employed to prepare a wax model with the desired defect shape, then a fixing device is used to fix the wax model onto a specific position in a casting mould of consolidation and thereafter a slurry is poured to form a grouting consolidation sample, after the grouting consolidation sample reaches the predetermined strength, the grouting consolidation sample containing the wax model is put into an oven to heat at a temperature above the melting point of wax to demolish the structure of the wax model to form a grouting consolidation sample with internal defects.