Hydrate remediation systems, apparatuses, and methods of making and using same including at least one pair of electrodes detachably or fixedly attached to a pipeline or flowline in a spaced relationship so that a current may be imposed across a section of the pipeline or flowline between each pair of electrodes resulting in electrical heating of the section for a time sufficient to raise a temperature of a fluid in the section of the pipeline or flowline to a temperature above a dissociation temperature of hydrates formed in the fluid.

A pipe snow removal device is supported for movement longitudinally along a pipe to clear snow and/or ice from the pipe. A main housing has boundary walls defining an outer boundary of a bounded space within a hollow interior of the main housing. An inner boundary of the bounded space is open to the pipe upon which the main housing is supported. A mounting arrangement supports the main housing relative to a work vehicle that is movable alongside the pipe to displace the main housing along the pipe. A heater heats the bounded space to melt the snow/ice on the pipe. A scraper assembly supported in leading relationship to the main housing clears loose snow before melting remaining snow and ice on the pipe as the housing passes.

The inventive concept provides an apparatus for treating a substrate by using a supercritical fluid. In an embodiment, the apparatus may include a process chamber that provides a treatment space, and including a chamber heater that increases a temperature of an interior of the treatment space, a substrate support provided in the treatment space and that supports the substrate, and a substrate heating member that heats a lower surface of the substrate while contacting the lower surface of the substrate.

This new application collects data from indoor and outdoor environments and with that data compiles databases, analyzes that data and finds relationships between pollutants, microbes, matter and diseases in humans, plants and animals. This new application is called the Artificial Intelligence Doctor. The application utilizes artificial intelligence, machine learning and parallel conveyor belts with imbedded microscope slides for the identification and analysis of microbes and matter. The application identifies microbes and matter using static electricity applied to microscope slides imbedded in conveyor belts using light microscopes, electron microscopes, polarized light microscopes, x ray machines, artificial intelligence and machine learning algorithms. The easy transfer conveyor belt system utilizes migration of microbes and microbes from drones and robots for easier identification.

A furnace system includes at least one wall that defines a workspace. The workspace includes an aircraft part to be cleaned. One or more vacuum pumps are configured to achieve a predetermined vacuum level in the workspace. A gas purifier is configured to remove impurities in a gas to create a purified gas, the purified gas being directed from the gas purifier into the workspace, the purified gas being of a purity and composition that is effective to disassociate oxides on a surface or in a crack of the aircraft part to be cleaned when the workspace is heated to a predetermined temperature and the predetermined vacuum level is achieved in the workspace.

The disclosure is based on a medical imaging apparatus with a scanner, a patient support apparatus and a housing, which is arranged on the scanner and/or on the patient support apparatus, wherein the housing comprises at least one functional housing shell, wherein the at least one functional housing shell comprises at least one sensor element for detection of a hygiene status on the at least one functional housing shell, at least one output element, which is embodied for a visual display of the hygiene status, and at least one cleaning element for cleaning a surface of the at least one functional housing shell.

Systems, methods, and devices for post-processing additively manufactured objects are disclosed herein. In some embodiments, a method includes receiving a plurality of additively manufactured objects having excess material thereon. The method can include removing the excess material from the plurality of additively manufactured objects by rotating the plurality of additively manufactured objects. The method can also include receiving sensor data indicative of a cleaning status of the plurality of additively manufactured objects. The method can further include adjusting, based on the sensor data, an operational parameter that enhances removal of the excess material from the plurality of additively manufactured objects.

A method for cleaning a receptor layer of a surface stress sensor according to an embodiment of the present invention includes, in a surface stress sensor that detects a change in surface stress of a thin film, the change being caused by a receptor layer disposed on a surface of the thin film, causing at least a part of a surface region of the thin film to generate heat or supplying heat to the receptor layer from the outside of the surface stress sensor. This makes it possible to easily perform efficient cleaning of a surface stress sensor such as a sensor that performs detection using a piezoresistor while avoiding structural complications as much as possible.

A method for cleaning a reflective photomask, a method of manufacturing a semiconductor structure, and a system for forming a semiconductor structure are provided. The method for cleaning a reflective photomask includes placing a photomask in a first chamber, and performing a dry cleaning operation on the photomask in the first chamber, wherein the dry cleaning operation includes providing hydrogen radicals to the first chamber, generating hydrocarbon gases as a result of reactions of the hydrogen radicals, and removing the hydrocarbon gases from the first chamber.

A sucker rod cleaning system includes an inductive heating device, a feed mechanism, a first support and a second support. An electromagnet of inductive heating device includes a wire coil head that is configured to inductively heat a sucker rod positioned within a heating zone. The feed mechanism is configured to feed a sucker rod through the heating zone in a feed direction. The first support is positioned on an upstream side of the wire coil head, and is configured to support a portion of a sucker rod as it is fed through the heating zone by the teed mechanism. The second support is positioned on a downstream side of the wire coil head, and is configured to support a portion of a sucker rod as it is fed through the heating zone by the feed mechanism.