An automatic sampling device (autosampler) is provided for continuous water sample collection and visual inspection for the presence of particulate solids in water sources. The autosampler is capable of collecting larger water samples, over a longer period of time, than typical inline monitoring and sampling methods. This provides more accurate information regarding the presence and concentration of particulate solids in the water sample as compared to most inline methods. More particularly, the autosampler includes a plurality of plastic pellet and powder capture nets (P3CNs), each of which is designed with nested nets for catching and retaining particulate solids of sequentially diminishing particle size along the flow path of the water sample. This enables easy determination of the presence of particulate solids, as well as a quick assessment of the different sizes of particulate solids present in the water samples by visual inspection of the P3CNs.

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 may be from two to four times the diameter of the scoop. The scoop defines a scoop face that is generally parallel to an axis of the tubular of the scoop. The scoop is mountable with a threaded connection that seals around the tubular. An additional seal may comprise a compression nut that allows orientation of the scoop within the pipeline whereupon the scoop orientation is fixed by tightening the compression nut. In one embodiment, the scoop is a single outer tubular with internal bi-directional flow.

An arrangement forming a lubricant circuit includes at least one lubricant line, at least one line branching that branches the lubricant line into a first branch and a second branch. The arrangement further includes at least one lubricant reservoir integrated into the first branch, and at least one line junction where the first branch and the second branch merge. The first branch is lockable and releasable.

A flowmeter includes a fluid collection chamber for receiving a fluid flow, an adjustable collection tube configured to receive a portion of the fluid flow to generate one or more first measured parameters of multiple measured parameters of the fluid flow, a sampling chamber configured to measure samples of the fluid flow to generate one or more second measured parameters of the multiple measured parameters of the fluid flow, and a control module in signal communication with the adjustable collection tube and the sampling chamber and including one or more processors by which the control module automatically performs certain operations. Such operations include determining multiple output parameters of the fluid flow based on the multiple measured parameters and multiple input parameters. Such operations further include controlling a size of the adjustable collection tube based on a property of the fluid flow.

A spa tub includes a spa shell configured to contain a volume of water; a circulation system configured to create a flow of the water to and from the spa shell; and a testing system configured to acquire water samples from the volume of water and to perform water quality tests on the water samples. The testing system includes a housing; a circulation pump disposed within the housing configured to acquire the water samples from the volume of water; a replaceable reagent cartridge removably received within the housing; and a water test assembly disposed within the housing. The water test assembly is configured to receive the water samples acquired by the circulation pump and a reagent from the reagent cartridge. The water test assembly is configured to mix the water samples and the reagent and to perform the water quality tests on the mixed water samples and reagent.

A method of analyzing particles present in a service fluid of a device includes analyzing the particles during operation of the device where a service fluid flows through a service fluid circuit of the device during the analyzing. The method further includes branching off a service fluid stream at a first branch point of the service fluid circuit, feeding the branched-off service fluid stream to a separation unit, branching the branched-off service fluid stream into a first service fluid stream and a second service fluid stream by the separation unit, feeding a majority of particles present in the branched-off service fluid stream to the first service fluid stream by the separation unit, and ascertaining at least one parameter of the particles fed to the first service fluid stream by an evaluation unit.

A method and a sampling tool for collecting particles from lubrication fluid of an engine are disclosed. The particles collected may be used to conduct analysis to diagnose a condition of the engine. The tool can be detachably connectable to a lubrication system of the engine. The tool comprises an inlet for receiving lubrication fluid from the lubrication system of the engine, a filter and a pump configured to induce a flow of the lubrication fluid through the filter.

A hydrogen sulfide sampler system for sampling for hydrogen sulfide in a fluid flow line includes a main tank in fluid communication with a fluid sample inlet line and a fluid sample outlet line. A plurality of sample bottles are in fluid communication with the main tank by way of the fluid sample outlet line. A drain tank is in fluid communication with the main tank by way of the fluid sample outlet line. A manifold assembly includes the fluid sample outlet line, the manifold assembly located between the main tank and the drain tank and further located between the main tank and the plurality of sample bottles. A return line is in fluid communication with the drain tank. An analysis system is operable to analyze a composition of a sample fluid contained within the main tank.

A cryogenic liquid sampling system including a chamber having affixed therein a sample pump to pull a cryogenic liquid sample from an external source and an enclosure. The enclosure includes a supply port to receive an input stream of a gas, an input port connected to the chamber via a vacuum line, a sample pump port connected to the chamber via a pump line and configured to feed therethrough gas received at the supply port to the sample pump, a vacuum device connected to the input port and configured to generate a vacuum within the chamber by pulling air from the vacuum line, and processing circuitry to control the vacuum device and the sample pump to perform transfer of a cryogenic liquid sample from the external source to an external device.

An electrode cleaning and calibration system generally comprises a sensor holder assembly machined from a block of solid acrylic or similar plastic material, which can accommodate a variety of types and sizes of sensors for use in monitoring and measurement of water processing and treatment processes. Examples of sensors suitable for use in the system include pH sensors, dissolved oxygen sensors, chlorine sensors, ozone sensors, total suspended solid sensors, mixed liquor suspended solid sensors, ammonia sensors, monochloramine sensors, and ultraviolent transmittance sensors.