The Situational Atmospheric Vectoring Equipment (abbreviated in this document as equipment) provides a system to disperse an aqueous liquid in a solid or gaseous form. In accordance with an embodiment of the invention, the equipment comprises: a pressure vessel or external source for the aqueous liquid, a mechanical pump if required, a pressure vessel for the cryogen, mechanical lines connecting the aqueous liquid and cryogen allowing for flow control, a nozzle for fluid acceleration and, optionally, a mechanical fan for dispersal. Previous inventions of this category require the proper environmental conditions are present whereas the equipment, as described in this text, does not have this limitation.

An air flow assembly, such as a fan assembly, and associated methods are shown that may include one or more media dispensing nozzles. Examples of assemblies and methods are shown that include nozzles located within hollow vanes. Other examples of fan assemblies and methods are shown that create multiple cross sectional vortices that may be useful to concentrate a dispersed media.

A method and apparatus to create falling snow for use at ski resorts, theme parks and test and training facilities for use with drones, motor vehicles, autonomous vehicles and aircraft components.

A method, in particular for generating snow from water, using a low-pressure hydraulic device having a pump unit, to which a purification system is connected, and a distribution device having at least one high-pressure pump, to which a high-pressure unit having a snow cannon and/or a different snow-generating unit is connected. In order for the bonding of the water molecules in the supermolecular water structure of the process water to change and the generation of snow to improve, according to the invention at least part of the water used is exposed to an ionization field and/or a polarization field while simultaneously being exposed to the effects of an alternating electromagnetic field so that a weaker bonding of the water molecules in the supermolecular water structure is achieved, resulting in an improvement in the absorption and transfer of heat. The invention further relates to a device for carrying out the method.

A water gathering and distribution system and related techniques for operating in freezing environmental conditions are disclosed. The system may include a water diverter unit or a water flow regulation unit configured to receive water from a water source situated at a location that is remote, inaccessible (or difficult to access), and/or experiences freezing environmental conditions and to deliver a controlled volume of that water for downstream use. The system further may include a water supply unit configured to receive that water and to supply it to downstream snowmaking equipment. In some instances, the supply unit also may cool the water to a temperature suitable, for example, for snowmaking. In a general sense, the disclosed system may be considered modular, in that multiple system components may be placed in flow communication with one another, as desired, to provide a distributed network of water collection and distribution elements.

An air flow assembly, such as a fan assembly, and associated methods are shown that may include one or more media dispensing nozzles. Examples of assemblies and methods are shown that include nozzles located within hollow vanes. Other examples of fan assemblies and methods are shown that create multiple cross sectional vortices that may be useful to concentrate a dispersed media.

Disclosed is a fan gun snowmaker that utilizes an external nucleation device to create atomized water mist that is broken apart and frozen by a transverse air jet to create frozen nuclei, or snow seed. Further, flat spray nozzles that are normally used for spray washing and power washing are used that create a flat fan spray at the opening of the fan gun, rather than typical cone-shaped sprayers. The fan spray better disperses the water molecules into the cold, ambient air, which then combine with the frozen nuclei to create snowflakes. The fan gun is portable and lightweight and has anchors at each end that also function as jacks.

A nozzle device and method for creating a fluid nucleation in situ, is disclosed. The nozzle has a housing having a hollow interior, an outer cylindrical wall, and inlet and an outlet, and a diffuser disposed in the cylindrical tube at a first end toward the inlet. The diffuser is configured to break bonds between adjoining fluid molecules and create a nucleation event. The nozzle further has a mesh framework disposed in the cylindrical tube and extending longitudinally within the tube in the nucleation zone, and is configured to manipulate the bonding and un-bonding of water molecules within a pressurized environment for the production of snow, clean water or both.

There is provided an apparatus for manufacturing powdered ice with salinity includes a water supply unit configured to supply a salted water; a spraying unit connected to the water supply unit and configured to generate a pressurized salted water-air mist; an ice generating unit connected to the spraying unit and configured to generate ice nuclei; a collecting unit connected to the ice generating unit and configured to grow the size of the powdered ice and to collect the powdered ice; and a reserving unit connected to the collecting unit and configured to transfer and store the powdered ice.

An air flow assembly, such as a fan assembly, and associated methods are shown that may include one or more media dispensing nozzles. Examples of assemblies and methods are shown that include nozzles located within hollow vanes. Other examples of fan assemblies and methods are shown that create multiple cross sectional vortices that may be useful to concentrate a dispersed media.