The present disclosure relates to electrostatic spraying solutions and, more particularly, to one or both of a novel system and nozzle apparatus for atomizing a liquid, such as a disinfectant, applying an electrostatic charge to the atomized liquid and then spraying the charged particles of the atomized liquid into the atmosphere. The need for efficient and effective disinfectant systems and methods is prevalent in the healthcare industry and travel industry, among others. The ability to quickly and effectively disinfect a hospital room, or a nursing home dormitory, or a cruise ship cabin is readily evident.
Electrostatic spraying systems known in the art either require manual operation or are incapable of automatically spraying an entire space, such as a room, without a human operator. Additionally, electrostatic spraying nozzle apparatuses known in the art are difficult to repair, prone to fouling, inconsistent in application of electrical charge, and difficult to calibrate such that a consistent atomization of a liquid is achieved.
Therefore, there is a need in the art for a 360-degree electrostatic spray cart that overcomes the deficiencies in the prior art relative to automated electrostatic spraying. Further, there is a need in the art for a new and improved electrostatic spray nozzle that overcomes the deficiencies in the prior art relative to electrostatic spray nozzles.
An exemplary induction electrostatic spraying nozzle according to the solution includes connections to operably couple to each of an electric power supply, a fluid chemical supply, and a compressed air supply. Further, the electrostatic spray nozzle includes an electrostatic charge component operably coupled to an electrode that energizes the electrostatic charge component. The electrostatic charge component defines a mixing chamber within the automated electrostatic spray nozzle. Actuation of the electrostatic spray nozzle causes atomization of a fluid flow from the fluid chemical supply, electrostatic charging of the atomized fluid flow, and discharging of the electrostatically charged atomized fluid flow from the electrostatic spray nozzle.
The electrostatic charge component that defines the mixing chamber within the electrostatic spray nozzle may be in the general shape or form of a frustum. Further, the electrostatic spray nozzle may include a removable cap component. The electrostatic charge component may be integrated within the removable cap component or, alternatively, may be separable from the removable cap component. Also, the electrostatic spray nozzle may include a body that includes a pair of locking tabs and a removable cap component that includes a complimentary pair of locking windows such that the removable cap component is operable to mechanically engage with the body when the locking windows receive the locking tabs.
Various embodiments, aspects and features of the present solution encompass either or both of an improved electrostatic spray nozzle and an improved electrostatic spraying system configured to be placed in an area, such as a room, and automatically spray in a 360-degree manner in a continuous rotation. As would be understood by one of ordinary skill in the art of electrostatic spraying, an electric charge may be applied to, or induced on, an atomized flow of chemical such that charged droplets of the chemical are electrically attracted to surfaces that may harbor pathogens or the like.
Embodiments of the solution in the form of a spray nozzle are advantageous over prior art spray nozzles for at least the reason that they may comprise an electrostatic charge cone positioned within a mixing chamber such that a high percentage of particles in an atomized liquid flow come into contact with the electrostatic charge cone prior to exiting the spray nozzle. By coming into contact with the electrostatic charge cone, an electric charge is efficiently induced to the particles. Also advantageously, embodiments of the solution in the form of a spray nozzle may comprise a nozzle cap configured to consistently engage mechanically with the body of the spray nozzle such that a mixing chamber sized in view of Boyle's law and other physical considerations is defined within the nozzle in a dimensionally consistent manner.
Embodiments of the solution in the form of an inductive electrostatic spraying system are advantageous over prior art systems for at least the reason that they may be used without manual operation and without need for repositioning to completely spray a target space. Notably, embodiments of an electrostatic spraying system according to the solution may or may not comprise an electrostatic spraying nozzle that includes an electrostatic charge cone positioned within a mixing chamber such that a high percentage of particles in an atomized liquid flow come into contact with the electrostatic charge cone prior to exiting the spray nozzle. Moreover, embodiments of an electrostatic spraying system according to the solution may or may not comprise an electrostatic spraying nozzle that includes a nozzle cap configured to consistently engage mechanically with the body of the spray nozzle such that a mixing chamber sized in view of Boyle's law and other physical considerations is defined within the nozzle in a dimensionally consistent manner.
Turning now to the figures,
As shown in more detail in subsequent figures, the electrostatic spray nozzle may be coupled to a rotary union such that the nozzle may be continuously rotated in a 360-degree pattern. Depending on embodiment and the executable program used to govern the spray pattern, the electrostatic spray nozzle may be rotated continuously in one direction for a duration of time (e.g., clockwise), or continuously in one direction for a first duration of time (e.g., clockwise) followed by continuously in a second direction for a second duration of time (e.g. counterclockwise). The electrostatic spray nozzle may also be configured to translate from an uppermost direction to a lower most direction (i.e., “up and down”) as it rotates. The electrostatic spray nozzle may also be held in a certain position for a relatively longer period of time than it is held in other positions, as may be dictated by the executable program. In these ways, an embodiment of the system 100 may be used to deliver a high degree of efficacy when applying a disinfectant to surfaces in a target space.
Additionally, embodiments of the system 100 may include a manual electrostatic spray gun 111 in addition to the automated electrostatic nozzle 207. Advantageously, the manual electrostatic spray gun 111 may be useful for an operator of the system 100 to manually apply electrostatically charged chemical spray to target surfaces within the space and/or to ensure that electrostatically charged spray is applied to hard to reach or critical areas within the space. The manual electrostatic spray gun 111 may be mounted on the exterior of the cabinet 106 or stored in its interior.
As can be seen in the
The air compressor 108 supplies compressed air to either the electrostatic spray nozzle 207 or the manual electrostatic spray gun 111. A valve 112B, such as but not limited to a three-way ball valve, diverts the compressed air to either of the electrostatic spray nozzle 207 or the manual electrostatic spray gun 111, as would be understood by one of ordinary skill in the art of valves. Similarly, valve 112A diverts chemical from pressurized chemical tank 113 to either of the electrostatic spray nozzle 207 or the manual electrostatic spray gun 111. It is envisioned that the valve 112B (as well as valve 112A) may be either manually operated or automated. In the
The air compressor 108 may also supply compressed air to the pressurized chemical tank 113 in order to pressurize the chemical for delivery to nozzle 207 or spray gun 111. Notably, although the exemplary embodiment of system 100 illustrated in
The power source converter 114 supplies DC electric power to the controller that, in turn, and according to a preprogrammed executable logic, supplies DC power to one or more of the solenoid 110, electrostatic spray nozzle 207, motor 202 and manual electrostatic spray gun 111. As can be understood from the
Returning to the operation of the electrostatic spray nozzle 207, the controller supplies the power supply to an electric motor 202 and a linear actuator 208 (not shown in the
As will become more clearly understood from the following figures, the electrostatic spray nozzle 207 (as well as the manual electrostatic spray gun 111) includes an internal mixing chamber wherein atomized liquid may come in contact with an energized electrode such that the atomized liquid becomes electrostatically charged. The compressed air lines, liquid supply lines and electrical supply wires, supply both the electrostatic spray nozzle 207 and manual electrostatic spray gun 111. With regards to the nozzle 107, the power supply provides electrical power for powering the tilt piston and internal electrode of the nozzle. The gearing 203 works to rotate the spray nozzle 207 in a continuous circular path. Depending on embodiment, the piston may be used to translate the spray nozzle 207 up and down while the gears 203 work to rotate the entire nozzle 207 along the aforementioned circular path (or some variation of the circular path). Alternatively, the piston 208 may be used to position the spray nozzle 207 at a fixed angle while the entire nozzle 207 is rotated. In these ways, embodiments of the solution may apply an electrostatically charged atomized liquid around and throughout an entire room without need for repositioning or translating back and forth along an arc less than a full circle.
Turning now to
As can be seen in the illustrations, the nozzle cap 305 includes an engagement window 307A configured and positioned to mechanically interface with a locking tab 312A protruding from the spray nozzle body 310. A complimentary engagement window 307B and locking tab 312B on the opposite side of the spray nozzle 300 cannot be seen in the
Referring specifically to the
As would be understood by one of ordinary skill in the art of spray nozzles, an atomizing orifice 317 may be configured and positioned to atomize a liquid supply with a pressurized air supply (i.e., finely divide a liquid stream into a flow of divided liquid particles). The atomized flow, upon exiting the atomizing orifice 317, fills a mixing chamber defined within the interior cavity of the nozzle cap 305. While in the mixing chamber, the atomized flow is exposed to the electrostatic charge cone 301 before exiting the nozzle 300 through aperture 303. The electrostatic charge cone 301, having been electrically energized by virtue of its contact with electrode 313, imparts an electrostatic charge on the droplets that form the atomized flow.
It is envisioned that, in some embodiments of an improved electrostatic spray nozzle according to the solution, the electrostatic charge cone 301 may be permanently integrated into the nozzle cap; however, in other embodiments of an improved electrostatic spray nozzle according to the solution the electrostatic spray cone 301 may be separable from the nozzle cap in order to facilitate easy cleaning and replacement.
The present solution has been described using detailed descriptions of embodiments thereof that are provided by way of example and are not intended to limit the scope of the solution. The described embodiments comprise different features, not all of which are required in all embodiments of the solution. Some embodiments of the present solution utilize only some of the features or possible combinations of the features. Variations of embodiments of the present solution that are described, and embodiments of the present solution comprising different combinations of features noted in the described embodiments will occur to persons of the art. Moreover, it will be appreciated by persons skilled in the art that the present solution is not limited by what has been particularly shown and described herein above. Rather the scope of the invention is defined by the claims that follow.
This is a utility patent application being filed in the United States as a non-provisional application for patent under Title 35 U.S.C. § 100 et seq. and 37 C.F.R. § 1.53(b) and claiming the benefit of the prior filing date under Title 35, U.S.C. § 119(e) of the U.S. provisional application Ser. No. 62/549,589, filed Aug. 24, 2017, and U.S. provisional application No. 62/549,598, filed Aug. 24, 2017, each application of which is incorporated herein by reference in its entirety and relied upon.
Number | Date | Country | |
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62549589 | Aug 2017 | US | |
62549598 | Aug 2017 | US |