Pressurized Growing Air System for Vertical and Horizontal Planting Systems

CROSS REFERENCE

This application is a reissue application of U.S. patent application Ser. No. 14/163,660, filed Jan. 24, 2014, now U.S. Pat. No. 9,578,819, issued Feb. 28, 2017, which claims priority of which are incorporated herein by reference (1) provisional application from U.S. Provisional Patent Application No. 61/849,339 , which is incorporated by reference in its entirety .

BACKGROUND

Indoor green walls using plants have been increasingly popular for aesthetics, improved air quality, humidity and natural cooling. Planting system both horizontal and vertical systems have been developed for air cleaning using the microbes living around plant roots for air cleaning. These green structures can pose a number of problems for the owner, mold, algae, and health issues from dirty catch basin reservoir. Drip irrigation or “eb flow systems are the most common methods of irrigation for vertical systems. Because each plant tray drains into the next consecutive tray all the dirt/debris flows into catch basin that is open and exposed to the indoor environment. Poor air circulation creates mold and algae problems, and poor growing conditions for the plants. The plants plant's ability to clean the air is inhibited by these issues and dramatically reduces the potential potentially healthy effects green walls can have. Aeroponic systems like U.S. Pat. No. 850,523B2 8,505,238 to Luebbers, Hensley, use spray methods for watering plants still resulting in a mixture of soil and debris in irrigation water which will frequently need to be cleaned. Drip vertical systems like patent #EP1416229A2 EP1416229A2 to Darlington, use an air permeable sub-straight substrate creating a similar problem of organic/dirt debris building up in containment reservoir. EP2654400A 1 to Paleszezak , discloses a series of pipes, with alternating prismatic shaped bins, for air circulation. W02011 019277 A2 WO2011019277A2 to Kluiver , discloses a system where indoor pollution is captured on the leaves of a plant and washed into substrate. System W0201 0033423A 1 WO 2010/033423A1 to Wolverton/Middlemark, use beds with various sized substrate to and drip irrigation to process indoor air through. U.S. Pat. No. 6,477,80582 6,477,805B2 to Ware , uses similar drip methods, again mixing irrigation water directly with planting mediums and debris. Therefore , it is the purpose of this invention to demonstrate an irrigation system that efficiently delivers water and air directly into planting substrate that does not need modification for air flow, while keeping irrigation water separate from living area. It is the purpose of this invention to use air movement to facilitate water movement over a modified wicking system into the soil, not using the capillary nature of the wick to do so as U.S. Pat. No. 4,741,125 to Donald Pengorest , where a bi an expandable metal control device is used for control. Further , U.S. Pat. No. 4,219,967 to Hickerson, relies on a wick system as well. Capillary wicks are used in many growing devices however controlling the moister they deliver is not easily achieved, leaving soil saturated and unhealthy. There for it is the purpose of this invention to control air and moisture delivery through a specifically designed nozzle that removes the need for electronic equipment for regulating moisture levels.

SUMMARY

The System Pressurized vertical-horizontal growing system solves a number of problems that convention irrigation systems have as well as growing systems for the purpose of Phytoremediation. Including phytoremediation, including the elimination of water catch basins, electronically monitoring equipment, or the need for specially modified planting mediums. This system while using a capillary wick does not require capillary “action” from the wick for moisture movement, but relies on air movement to create a “negative” negative air pressure build up for drawing water into the soil substrate. This process created by the air channel location within the wick is self regulating self-regulating . Whereas the more Greater air flow moving through the system the causes more water movement , thus creating a balance with the water to air ratio insuring ensuring healthy roots and plants without relying on electronic equipment. It is also a benefit of the process to create a microclimate and moisture rich area around the plant grown, this is accomplished by the movement of air “pushing” through the soil. In addition , our air flow rates are more favorable to total filtration per pass of air due to slower rates. In addition , air filtration can be targeted to specific areas where air remediation is needed.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 Shows shows a curved nozzle for vertical system ( 1 ) and nozzle with collar ( 6 ) for positioning nozzle in the correct depth. ( 2 ) shows air channel for moving air through ( 1 ) nozzle. Pot collar ( 7 ) holds pot the proper distance from channel. Recessed air channel ( 5 ) ends ⅛-¼ inch from nozzle opening to insure negative pressure build up in nozzle ( 1 , 2 ) .

FIG. 2 Shows shows a straight nozzle ( 1 ) for horizontal growing channels with air channel ( 2 ) and ( 5 ) recessed air chamber .

FIG. 3 Demonstrates the shows a curved nozzle ( 1 ) with a fiberglass wick ( 4 ) inserted and ( 8 ) air flow out of tube from channel. FIG. 8 ( 9 , 13 ) to see channel. ( 5 ) shows recess in air chamber to create the negative pressure on the wick for water movement .

FIG. 4 Is is a front look at an end of a nozzle ( 1 ) tube end ( 3 ) shows the air channel and nozzle end without the fiberglass wick .

FIG. 5 Demonstrates shows a straight nozzle ( 1 ) for a horizontal applications with which ( 4 ) nozzle stop ( 6 ) and air flow out of nozzle ( 8 ) growing system .

FIG. 6 Is is a side view of horizontal panel ( 15 ) showing nozzles ( 1 ) seated into channel with which ( 4 ) hanging in irrigation water ( 17 ) irrigation water needs to be 2 inches from base of nozzle ( 1 , 18 ) for process to work properly a channel of a horizontal growing system .

FIG. 7 Is is a front cut away look at a horizontal channel ( 15 ) showing irrigation water ( 17 ) and distance between irrigation water and nozzle base ( 28 ) multiple adjacent channels of a horizontal growing system .

FIG. 8 Shows is a cross section of air channel ( 9 ) with view of a system that includes a planting pot ( 12 ) pot is hanging on rail ( 19 ) and seated into nozzle ( 1 ) wick ( 4 ) is hanging in irrigation water ( 11 ) with the two inch space ( 28 ) between the bottom of nozzle ( 1 ) and irrigation water ( 11 ) Air and moisture from channel ( 9 ) move into the soil with microbes ( 14 ) Clean remediated air leave planting pot ( 12 ) from top of pot bathing plant in humid air ( 16 ) .

FIG. 9 depicts shows the embodiment of the system shown in FIG. 8 having that has connected chambers that contain channels containing indoor air and a small reservoir of water.

DETAILED DESCRIPTION

Water/air delivery system for a vertical and horizontal plantings that enables water, air and heat (if needed) delivery through a single pressurized system in conjunction with a targeted delivery nozzle designed to efficiently combine air and water in tandem while keeping soil substrate adequately moist for plant and microbe growth. This system enables High high air volumes to be pumped through root zones enhancing the process of Phytoremediation phytoremediation . System is scalable for small consumer growing system and to large commercial applications. This system eliminates the need for separate water drainage/reservoir catch basins, electronic sensing or timers for watering. This system also conserves energy with targeted nozzles that deliver water, air and optional heat to each growth container. Nozzles can be removed from the system when not in use so no energy or water will be used. Nozzle uses absorptive wick but does not rely on capillary action for moving moisture, rather uses air flow targeted directly behind wick end to propel moisture into growing container soil medium from a “negative” negative pressure build up created within the nozzle. Thus , the purpose of this system is to adequately provide air and water to a system (disclosed in U.S. provisional patent Provisional Patent Application No. 61/849,339 ) that plants roots for air cleaning while keeping water for irrigating the system isolated from rooms interior.

FIG. 1 shows a curved nozzle 1 for a vertical growing system. The nozzle 1 includes a collar 6 for positioning the nozzle 1 at a correct depth. The nozzle 1 includes an air channel 2 for moving air through the nozzle 1 body. A pot collar 7 holds pot at a proper distance from an air channel. The air channel 2 terminates at point 5, which is ⅛-¼ of an inch from a nozzle opening. This ensures a buildup of a negative pressure build up inside the nozzle.

FIG. 2 shows a straight nozzle 1 for a horizontal growing system. The nozzle 1 includes an air channel 2 that terminates at point 5.

FIG. 3 shows a curved nozzle 1 with a fiberglass wick 4 inserted into the nozzle 1. Air flow 8 includes air flowing out of the nozzle 1. Air channel 2 terminates at point 5. A negative pressure build up is inside the nozzle 1 to provide for water movement.

FIG. 4 is a front look at an end of a nozzle. A divider 3 creates two channels within the nozzle body. The two channels include an air channel 2 through which air moves through the nozzle body, and another channel through which air and water moves through the nozzle body.

FIG. 5 shows a straight nozzle 1 for a horizontal growing system. The nozzle 1 includes a collar 6 for positioning the nozzle 1 at a correct depth. The nozzle 1 includes a wick 4. Air flow 8 includes air flowing out of the nozzle 1.

FIG. 6 is a side view of a channel 15 of a horizontal growing system. Multiple nozzles 1 are seated into the channel 15 with corresponding wicks 4 hanging in irrigation water 11. Irrigation water 11 needs to be two inches from the base of each nozzle 1 for the irrigation process to work properly.

FIG. 7 is a front view of multiple adjacent channels 15 of a horizontal growing system

FIG. 8 is a cross section view of a system that includes a chamber 13 and a planting pot 12. The planting pot 12 hangs on a rail 19 and is seated into a portion of the nozzle 1 and the wick 4. The opposite end of the wick 4 hangs in irrigation water 11 with the two-inch distance between the bottom of the nozzle 1 and the irrigation water 11. Air and moisture is moved from chamber 13 to the soil substrate 14 in the planting pot 12 through the nozzle 1 and wick 4. Clean remediated air leave planting pot 12 from top of pot bathing plant in humid air 16.

This system embodies connected chambers ( FIG. 9 ) that FIG. 9 shows the embodiment of FIG. 8 having connected channels that contain indoor air and a small reservoir of water. The embodiment shown in FIG. 9 contain indoor air and a small reservoir of irrigation water 17 , 11 that can either be fed continuously or intermittently with a pump or direct water feed using a solenoid and a timer. Nozzle 1 placement in the system is critical and needs to be set into the system so water does not mix with the nozzle 1 system. Only air enters the nozzle 1 which in turn creates a negative pressure build up via the recessed air channel which draws the water into the substrate.

The Growing growing apparatus may be for cleansing air and watering plant, wherein the apparatus includes a modular panel constructed for either vertical or horizontal planting systems, including connecting couplers 19 and end caps 20 for directing water flow from upper to lower channels 22 . The panel consist of five (5) channels per section with opposing conical top and bottom set at 45 degree 45-degree angles 23 for both channeling water and accepting irrigation nozzle. Note, the system can also use a horizontal channel system as FIGS. 7 and 8 demonstrate, while the orientation is different, the function is the same. Panels 24 stack nesting consecutively on top of each other to make larger systems. Panels may have an attached rail 25 for accepting and hanging planting container.

The panels may have ports 20 and 21. Port 20 can be used for accepting water. Port 21 can be used for accepting “air” 21 and “water” 20 from an external fan 28 ( or blower ). as well as Port 20 can be used for accepting water from a pump or direct water feed using a solenoid and a timer. The panels may also include a drain 26 located at the bottom of the last run for draining the system. End connecting caps that extend upwards into bottom of channel 27 restricting and holding water in the base of the channel as well as the channel within the end cap for directing water flow to the bottom of next consecutive channel.

Air ports 21 at the top of the air chambers 2 may be for the purpose of air direction forced in a downward flow to alleviate water and air “mixing” within the nozzle. The system may create separation of irrigation water in channel 11 from soil substrate 10 14 by positive pressure within said channel air chamber 13 insuring ensuring no mixing of the irrigation water 11 and planting medium 10 soil substrate 14 occurs.

The system may use a wicking system/nozzle nozzle 1 that is spaced from a distance of 2-3 inches from the water source irrigation water 11 to the base of the nozzle holding wick in center of channel to insure ensure no mixing of water and air occur. The nozzle 1 may use a separate air chamber channel 2 for efficiently moving air out of said chamber 28 13 without extreme pressure build up. The system may utilize said the nozzle 1 and air chamber channel 2 that is recessed back 1 / 8 - 1 / 4 inch to direct air volume over end of exposed wick 4 to facilitate water movement into soil rooting media Wherein without directed air movement over said wick moisture movement would not occur. The system may use air movement through said the air chamber channel 2 into said the nozzle 1 as a means for irrigating a plant.