Electrosprayer space watering system

Abstract

The subject invention is an electrostatic plant watering system for the delivery of water and nutrients to the roots of plants. The system provides water or another fluid from a fluid source or container using a pump. The pump provides a pressurized fluid at a constant flow rate through a nozzle at a low pressure, which sprays a fine mist of particles through a conductive metallic ring that is electrically charged by a voltage source. As the fluid particles pass through the center of the electrically charged ring, the particles themselves become charged, allowing them to attach to the roots of a target plant positioned at a selected distance away from the electrostatic plant watering system.

Claims

1. An electrostatic plant watering system comprising: a fluid source connected to a pump with a pressurizing end and an output end that provides a pressurized fluid at a constant flow rate; a nozzle with a connecting end that fastens to the output end of the pump, an outer surface, and an output surface that atomizes the pressurized fluid into a fine mist of fluid particles; an electrically insulating housing with an interior surface that is secured to at least a portion of the outer surface of the of the nozzle and an exterior surface; an electrode ring housing with an inner surface that is secured to the exterior surface of the electrically insulating housing and extends past the nozzle; a conductive metallic ring embedded in the bottom surface of the electrode ring housing positioned so that the fine mist passes through the metallic ring; and a voltage source connected to the metallic ring connected via a lead wire through a lead port through the electrode ring housing, wherein the fine mist of fluid particles becomes electrostatically charged as it flows past the conductive metallic ring when voltage is applied allowing the fine mist of fluid particles to attach to a primary target positioned at a selected distance away from the electrostatic plant watering system.

2. The electrostatic plant watering system of claim 1, wherein the pump is a syringe pump.

3. The electrostatic plant watering system of claim 1, wherein the pressurized fluid comprises a fluid pressurized between 35 mL/min and 360 mL/min.

4. The electrostatic plant watering system of claim 1, wherein the pressurized fluid comprises water, a nutrient solution, a fertilizer, or a pesticide.

5. The electrostatic plant watering system of claim 1, wherein the constant flow rate comprises a rate between 35 mL/min and 360 mL/min.

6. The electrostatic plant watering system of claim 1, wherein the electrically insulating housing comprises plastic, porcelain, a fiber composite, or rubber.

7. The electrostatic plant watering system of claim 1, wherein the electrode ring housing comprises plastic, porcelain, a fiber composite, or rubber.

8. The electrostatic plant watering system of claim 1, wherein the conductive metal ring comprises copper, aluminum, gold, silver, steel, or brass.

9. The electrostatic plant watering system of claim 1, wherein the conductive metal ring is positioned between 0 millimeters and 10 millimeters from the output surface of the nozzle.

10. The electrostatic plant watering system of claim 1, wherein the diameter of the conductive metal ring is greater than the diameter of the output surface.

11. The electrostatic plant watering system of claim 1, wherein the conductive metal ring is covered by a material comprising plastic, epoxy, or rubber.

12. The electrostatic plant watering system of claim 1, wherein the voltage source applies a voltage from about 1 kV to about 10 kV to the metallic ring.

13. The electrostatic plant watering system of claim 1, wherein the primary target comprises the roots of a plant.

14. The electrostatic watering system of claim 1, wherein the primary target is positioned between four inches and twelve inches away from the electrode ring housing.

15. The electrostatic plant watering system of claim 1, wherein an electrically conductive secondary target is placed behind the primary target.

16. The electrostatic plant watering system of claim 15, wherein the electrically conductive secondary target is a metal orb.

17. An electrosprayer system comprising: a fluid source connected to a pump with a pressurizing end and an output end that provides a pressurized fluid at a constant flow rate; a nozzle with a connecting end that fastens to the output end of the pump, an outer surface, and a output surface that atomizes the pressurized fluid into a fine mist of fluid particles; an electrically insulating housing with an interior surface that is secured to at least a portion of the outer surface of the of the nozzle and an exterior surface; an electrode ring housing with an inner surface that is secured to the exterior surface of the electrically insulating housing and extends past the nozzle; a conductive metallic ring embedded in the bottom surface of the electrode ring housing positioned so that the fine mist passes through the metallic ring; and a voltage source connected to the metallic ring connected via a lead wire through a lead port through the electrode ring housing, wherein the fine mist of fluid particles becomes electrostatically charged as it flows past the conductive metallic ring when voltage is applied allowing the fine mist of fluid particles to attach to a primary target positioned at a selected distance away from the electrostatic plant watering system.

18. A method of using the electrostatic plant watering system in microgravity, comprising the steps of: providing an electrostatic plant watering system comprising a fluid source, a fluid, a pump, a nozzle, an electrically insulating housing, an electrode ring housing, a conductive metallic ring, an electrical power source, a lead wire, and a primary target; adding the fluid to the fluid source; supplying an electrical power source to the system, wherein the electrical power source provides an electrical charge to the conductive metallic ring via the lead wire; selecting a distance between the electrostatic plant watering system and the primary target; and activating the pump to pressurize the fluid and supply the pressurized fluid to the nozzle, wherein the nozzle atomizes the fluid into a fine mist of particles before the particles pass through the conductive metallic ring, thereby electrically charging the fluid particles so that they attach to the primary target.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1a depicts an embodiment of the present invention.

(2) FIG. 1B depicts an exploded view of a subsystem of an embodiment of the present invention.

(3) FIG. 1c depicts a cross-section of the electrode ring housing, cut along line A-A, of an embodiment of the present invention.

(4) FIG. 1d depicts an embodiment of the primary target and secondary target of the present invention

DETAILED DESCRIPTION OF THE INVENTION

(5) Referring to FIGS. 1a, 1b, 1c, and 1d, the present invention is an electrostatic plant watering system 100 for the delivery of water and nutrients to plants. The electrostatic plant watering system 100 comprises a fluid source 101 connected to a pump 102 with a pressurizing end 104 and an output end 106 that can provide a pressurized fluid 108 at a constant flow rate through a nozzle 110. Suitable fluid sources 101 can be a hose, vessel, reservoir, tank, or any other source or container known to one of skill in the art. Suitable materials for the fluid source 101 can be rubber, plastic, metal, fiber composite, or any other material known to one of skill in the art for storing or conveying fluids. In a preferred embodiment, the fluid source 101 is a plastic container. A suitable pump 102 can be a syringe pump, cyclic pump, pressurized fluid tank, or any other pump known to one of skill in the art that can provide a pressurized fluid 108 at a constant flow rate. In a preferred embodiment, the pump 102 is a syringe pump. The fluid source 101 and the pump 102 can be connected by any connection method or mechanism known to one of skill in the art.

(6) A connecting end 112 of the nozzle 110 fastens to the output end 106 of the pump 102, and an output surface 114 of the nozzle 110 that atomizes the pressurized fluid into a fine mist of fluid particles 109. In a preferred embodiment, the pressurized fluid 108 is pressurized to a pressure between two bar and ten bar, and the pump 102 provides the pressurized fluid 108 at a constant flow rate between 35 mL/min and 360 mL/min. In addition, the particle size of the fine mist of fluid particles 109 can be anywhere between 20 to 100 microns. For the purposes of the present invention, “fine mist” is defined by the flow rates and sizes above. Suitable pressurized fluids 108 include water, hydroponic nutrient solutions (which in one embodiment would include a mixture of water and plant nutrients customized for the plant species being grown), Hoagland's solution, fertilizers, pesticides, and similar fluids known to one of ordinary skill in the art. In a preferred embodiment, the pressurized fluid 108 is water. In another preferred embodiment, the pressurized fluid 108 is a hydroponic nutrient solution. The fluid 108, 109 used can be customized for agricultural uses, but it can also potentially be adapted for other industrial uses by one of ordinary skill in the art.

(7) At least a portion of the outer surface of the nozzle 110 is secured to the interior surface 116 of an electrically insulating housing 118. The electrically insulating housing 118 can be made from any electrically insulating material, such as plastic (including Delrin, Teflon, Ultem, polylactic acid (PLA), and Polyether ether ketone (PEEK), among others), porcelain, fiber composites, rubber, and other similar electrically insulating materials known to one of ordinary skill in the art.

(8) The exterior surface 120 of the electrically insulating housing 118 is secured to the inner surface 122 of an electrode ring housing 124 so that a portion of the electrode ring housing 124 extends past the nozzle 110. The electrode ring housing 124 can be made from any electrically insulating material, such as plastic (including Delrin, Teflon, Ultem, polylactic acid (PLA), and Polyether ether ketone (PEEK), among others), porcelain, fiber composites, rubber, and other similar electrically insulating materials known to one of ordinary skill in the art. In a preferred embodiment, both the electrically insulating housing 118 and the electrode ring housing 124 are constructed from a durable plastic that can be 3D printed. This not only allows the housings 118, 124 to be durable while in contact with the fluid 108, 109, but it also allows astronauts to quickly 3D print replacement housings 118, 124 should they fail.

(9) A conductive metallic ring 126 is embedded in the bottom surface 128 of the electrode ring housing 124, positioned so that the fine mist of fluid particles 109 passes through the conductive metallic ring 126. The electrode ring housing 124 extends past the output surface 114 of the nozzle 110 to provide sufficient distance between the output surface 114 and the ring 126 so that the ring 126 can ionize substantially all of the fine mist 109. In a preferred embodiment, the diameter of the ring 126 is larger than the diameter of the output surface 114 of the nozzle 110. Also in a preferred embodiment, the conductive metal ring 126 is embedded in the electrode ring housing 124 so that it is positioned 0 millimeters to 10 millimeters away from the output surface 114 of the nozzle 110.

(10) The conductive metallic ring 126 can be made from any electrically conductive metal, such as copper, aluminum, gold, silver, steel, brass, and other similar electrically conductive metals known to one of ordinary skill in the art. In a preferred embodiment, the conductive metallic ring 126 is made from copper.

(11) In one embodiment, a portion of the conductive metallic ring 126 is covered by a ring cover 128. The ring cover 128 can be an insert or other material that covers any exposed surface of conductive metallic ring 126. The ring cover 128 can be made from any electrically insulative material, such as plastic, epoxy, rubber, or any other electrical insulator known to one of ordinary skill in the art. The ring cover 128 protects the conductive metallic ring 126 and prevents fluid particles from coming into contact with the conductive metallic ring 126, which could cause an electrical short.

(12) A voltage source 130 is connected to the conductive metallic ring 126 via a lead wire 132 through a lead port 134 through the electrode ring housing 124. The voltage source 130 can be any source known to one of ordinary skill in the art, and the voltage may be selected by one skilled in the art to provide sufficient charge to the ring 126 to ionize the fine mist of fluid particles 109. In a preferred embodiment, the voltage applied is 1 kV to 10 kV.

(13) The fine mist of fluid particles 109 becomes electrostatically charged as it flows past the conductive metallic ring 126 when voltage is applied. This allows the now electrically charged fine mist of fluid particles 109 to attach to a primary target 136 (e.g., the roots of a plant) positioned at a selected distance away from the electrostatic plant watering system 100. While the system 100 can be adapted by one of skill in the art to spray the primary target 136 at varying distances, in a preferred embodiment, the distance between the primary target 136 and the system 100 is four inches to twelve inches.

(14) In situations where the primary target 136 (e.g., the roots of the target plant) of the electrostatic spraying system 100 is electrically conductive but cannot be easily grounded, a secondary target 138, or an artificial target, that is grounded is beneficial. The primary target 136 can be placed inside of the secondary target 138, or the secondary target 138 can be placed behind the primary target 136. The secondary target 138 can be made from any electrically conductive material, such as copper, aluminum, gold, silver, steel, brass, conductive fabrics, conductive foams, and other similar electrically conductive metals known to one of ordinary skill in the art. In a preferred embodiment, the secondary target 138 is made from brass. In another preferred embodiment, the secondary target 138 is made from steel. In addition, the secondary target 138 can be an orb or sphere, a flat plate, a sheet of fabric, a cube, or any other shape selected by one of skill in the art to allow for the charged fluid particles 109 to attach to the primary target 136. In a preferred embodiment, the secondary target 138 is a sphere. Since the secondary target 138 would need to be grounded, it may be connected to a ground by a wire, shaft, plate, or other ground connection known to one of skill in the art.

(15) If the primary target 136 is not electrically conductive (e.g., lunar regolith), one of skill in the art would need to pre-charge the primary target 136 to the opposite polarity of the fine mist of fluid particles 109 to attract the charged fluid particles 109. In situations where the target of the electrostatic spraying system 100 is electrically conductive and the target can be easily grounded, an artificial target 138 is not required.

(16) The present system 100 generally provides a pressurized fluid 108 from a fluid source 101 using a pump 102. The pump 102 provides a pressurized fluid 108 at a constant flow rate through a nozzle 110 at a low pressure, which sprays a fine mist of particles 109 through a conductive metallic ring 126 that is electrically charged by a voltage source 130. As the fluid particles 109 pass through the center of the electrically charged ring 126, the particles 109 themselves become charged, allowing them to attach to a primary target 136 positioned at a selected distance away from the electrostatic plant watering system 100.

(17) FIG. 1B shows an exploded view of a subsection of the system 100. Specifically, the figure highlights the nozzle 110, the electrically insulating housing 118, and the electrode ring housing 124.

(18) FIG. 1c shows a cross-section of ring housing 124 along line A-A to highlight the relationship of the ring housing 124, the conductive metallic ring 126, the ring cover 128, the lead wire, and the lead port 134.

(19) FIG. 1d shows the primary target 136 that would be positioned at a distance away from the system 100 and the secondary target 138 proximate to the primary target 136.

(20) In a method for using the preferred embodiment of the electrostatic plant watering system described above, in the first step, the user provides an electrostatic plant watering system comprising a fluid source, a fluid, a pump, a nozzle, an electrically insulating housing, an electrode ring housing, a conductive metallic ring, an electrical power source, a lead wire, and a primary target. In another embodiment of this method, the user provides a plant watering system that also comprises a secondary target.

(21) In another embodiment of this method, the electrostatic plant watering system is used in microgravity, which for the purposes of this application is an environment without gravity or any environment with lower gravitational force than on Earth. Such microgravity environments include in space; on spacecraft; on the surface of an extraterrestrial body such as asteroids, the moon, other planets and their surrounding moons; and any other such environments known to one of skill in the art.

(22) In the second step, the user adds a fluid to the fluid source. Suitable fluids include water, hydroponic nutrient solutions (which in one embodiment would include a mixture of water and plant nutrients customized for the plant species being grown), Hoagland's solution, fertilizers, pesticides, and similar fluids known to one of ordinary skill in the art. In a preferred embodiment, the fluid is water. In another preferred embodiment, the fluid is a hydroponic nutrient solution. The fluid used can be customized for agricultural uses, but it can also potentially be adapted for other industrial uses by one of ordinary skill in the art.

(23) In the third step, the user supplies an electrical power source to the system that provides an electrical charge to the conductive metallic ring via the lead wire. The power source also provides power to the pump (if required to operate the pump selected) and supplies the voltage source to the conductive metallic ring via the lead wire. The electrical power source can be an electrical plug, battery, or any other source know to one of ordinary skill in the art.

(24) In the fourth step, the user selects a distance between the system and the primary target. While the system can be adapted by one of skill in the art to spray the primary target at varying distances, in a preferred embodiment, the distance between the primary target and the system is four inches to twelve inches.

(25) In the final step, the user activates the pump to supply a pressurized fluid to the nozzle to atomize the fluid into a fine mist of fluid particles. As the fluid particles pass through the electrically charged conductive metallic ring, the particles become electrically charged. The now electrically charged particles are attracted to the primary target, and their electrical charge allows the particles to attach to the primary target. The pump can be turned on or activated using any activation method known to one of skill in the art, such as a switch or button.

(26) In another embodiment of the method of using the plant watering system, an additional step can be added between the third step and the fourth step when the primary target provided is electrically conductive but not electrically grounded, the user places a electrically conductive secondary target that is electrically grounded below or proximate to the primary target.

(27) The shapes and sizes of the elements of the present invention described above can be selected by one of skill in the art that will allow the selected fluid to flow and charge properly. Preferably, the elements and ring are circular and cylindrically shaped to promote constant and controllable flow of fluid.

(28) What is described herein are specific examples of many possible variations on the same invention and are not intended in a limiting sense. The claimed invention can be practiced using other variations not specifically described above.