TITLE' VERTICAL PLANT SUPPORTING SYSTEM
FIELD OF THE INVENTION
[0001] The present invention relates to the field of vertical plant supports, and more particularly to apparatus and methods for living walls.
BACKGROUND OF THE INVENTION [0002] A living wall is a vertical garden Vertical gardens can be mounted against a wall, or can be used independently as a privacy barrier A single or multi-sided vertical garden can also be used as a freestanding architectural feature. Livmg walls may be located both indoors and out, and offer many functional, environmental and aesthetic benefits [0003] In exterior applications, living walls provide a form of urban agriculture or urban gardening, providing good use of otherwise unutilized vertical surface areas. They may be built as a work of art for their own sake, or they may bθ incorporated into roadside advertising or other commercial display applications. Functionally, a living wall can clad an existing structural wall thereby extending the lifespan of traditional exterior wall materials and reducing heating and cooling energy costs
[0004] Indoors, living walls can provide a pleasing natural feature for building occupants. They can also improve the quality of re-circulated air with the photosynthetic production of Oxygen and by providing bacteria on the roots of the plants that metabolize air impurities such as volatile organic compounds. So called active walls may be joined to a building's air circulation system where fans blow air through the wall and then re-circulate the air throughout the building. Some active walls are kept behind glass to create more predictable airflow effects. Inactive walls have no mechanized air circulation Instead, they are kept open to promote as much free air circulation as possible.
[0005] Living walls, both indoor and outdoor, also provide a means for water reuse, at least as utility water. The plants of a living wall may purify slightly polluted water (such as greywater) by digesting the dissolved
nutrients, with Bacteria mineralizing the organic components to make them available to the plants.
[0006] Typically, a living wall will be either freestanding or installed directly on an existing wall surface Many systems use a lightweight mineral substrate of different sizes with pockets of growing medium, alternative rainwater, drip or mist watering systems, and planting selected for the particular microclimatic conditions at its installed location.
[0007] The vegetation of living walls is typically grown from seed after the other components of the living wall are installed. This growing period results in increased maintenance costs, loss of growth medium from wind erosion in exterior applications and other natural forces, and delays the realization of benefits from the living wall. Living walls installed in this fashion are also typically permanent or semi-permanent fixtures and, as such, render repairs to the underlying wall difficult and expensive [0008] In cases where living walls are installed on existing structural walls, significant alterations may be required to the existing wall surface to accommodate a permanent or semi-permanent installation. Existing cladding may not be capable of suitable attachment, or sustaining long-term direct contact with water and growth media. Permanent and semi-permanent installations are also typically static in their design, with the structure and site- grown planl selection being established at the time of installation Any desired structural or planting changes, for either functional, commercial or aesthetic reasons, would require disrupting or replacing the established living wall, thereby incurring more maintenance costs and delays in benefit from the new living wall design.
[0009] Thus, there is a need for an improved vertical plant support for use in a living wall application that overcomes some or all of the disadvantages evident in current living wall designs
BRIEF DESCRIPTION OF THE DRAWINGS [0010] In (he accompanying drawings,
[0011] Figure 1 illustrates a front isometric view of a vertical plant supporting system in accordance with the present invention;
[0012] Figure 2 is a back isometric view of the vertical plant supporting system of Figure 1 , [0013] Figure 3 is a side view of the vertical plant supporting system of
Figure 1 ;
[0014] Figure 4 is a front view of the vertical plant supporting system of
Figure 1 ,
[0015] Figure 5 is a back view of the vertical plant supporting system of Figure 1 ;
[0016] Figure 6 is a top view of the vertical plant supporting system of
Figure 1 ; and
[0017] Figure 7 is a bottom view of the vertical plant supporting system of Figure 1 [0018] Figure 8 is a perspective view of an alternate embodiment of the vertical plant support,
[0019] Figure 9 is a perspective view of an alternate embodiment of the vertical plant support,
[0020] Figure 10 is a perspective view of an alternate embodiment of the vertical plant support;
[0021] Figure 11 is a perspective view of a living wall comprising a plurality of vertical plant supports,
[0022] Figure 12 is a perspective and detail illustration of an example means of connecting adjacent vertical plant supports for use in a living wall application;
[0023] Figure 13 is a perspective view and detail of an example method of mounting vertical plant supports to a vertical surface;
[0024] Figure 14 is perspective view and detail of other methods of hanging a vertical plant support;
[0025] Figure 15 is a rear perspective view of a vertical plant support with one form of irrigation, [0026] Figure 16 is a partial side view of a vertical plant support and trough,
[0027] Figure 17 is a side view of a vertical plant support with misting irrigation;
[0028] Figure 18 is another embodiment of a vertical plant support for use in cleaning greywater,
[0029] Figure 19 is a partial perspective view of a vertical plan support with additional rooting holes;
[0030] Figure 20 is a side view of another irrigation system comprising a pump to recycle liquid; [0031] Figure 21 is a collection of views of another embodiment of a vertical plant support,
[0032] Figure 22 is a collection of views of an alternate embodiment of a vertical plant support of Figure 21 , and
[0033] Figure 23 are isometric views of the vertical plant support of Figure 21 , and
[0034] Figure 24 is a photograph of a vertical plant support with vegetation supported therein.
DETAILED DESCRIPTION OF THE INVENTION
[0035] Referring to Figures 1 to 7, there is generally illustrated one embodiment of a vertical plant support 10 in accordance with the present invention having a wall 20 and a matrix of tubes 30. Wall 20 comprises a panel 22 and an anchor layer 24 oriented so that the anchor layer 24 is positioned intermediate the panel 22 and the matrix of tubes 30. The matrix of tubes 30 can be arranged as any regular or irregular array or arrangement
of tubes Each tube is open at the front portion to provide an aperture through which plants grow, and at the rear portion adjacent the anchor layer 24 so that the plant roots may grow into the anchor layer 24 Preferably, anchor layer 24 is exposed along an upper edge 26 and a lower edge 28 while intermediate the panel 22 and matrix of tubes 30 Also preferably, vertical plant support 10 is provided with at least one means for attaching the vertical plant support 10 to a vertical structure or support In the illustrated embodiment, an advantageous hanging element 50 is shown connected to the upper portion of the wall 20 and extending rearward therefrom Hanging element 50 defines a hanging surface 52 adapted to mate with a cooperating portion of a vertical structure or support (not shown) Vertical plant support 10 may also include one or more feet 54 sized to space the vertical plant support 10 from its supporting structure Feet 54 can be sized to project rearward a distance similar to the hanging supports 50, or they may be longer or shorter thereby causing to vertical plant support 10 to deviate from a vertical orientation
[0036] Vertical plant support 10 may be manufactured from several individual components that are fastened together by welding, adhesives or other bonding or fastening methods or it may be moulded to form one or more pieces that are then connected together [0037] In the embodiment depicted in Figures 1 to 7, wall 20 is shown to be generally rectangular, and the volume of the matrix of tubes 30 is defined by a parallelepiped With consideration of the discussion below, it will be apparent to one skilled in the art, that the perimeter shape and volume defined by vertical plant support 10 may be modified and still be within the scope of the invention disclosed herein, all of which is intended to be included in this description.
[0038] Typically, anchor layer 24 is a porous sheet of regular or irregular three-dimensional mesh or screen For example, anchor layer 24 may be a sheet of intertwined fibers, wire, or coated wire Anchor layer 24 can be made of any suitable material including, but not limited to, plastics such as such as polyester, polyethylene, polyvinyl chloride, and polypropylene, wires
made of metals such as steel and copper, organic materials such as hemp, rockwool, wood fibers, and coconut fibers, and combinations thereof It has been found particularly advantageous to use a combination of natural and synthetic fibres. Natural fibres have a natural wicking ability that helps transport water add nutrients to the plants. Synthetic fibres offer a stable, long-lasting structure to support root growth
[0039] Panel 22 and the matrix of tunes 30 can be made of any suitable material including, but not limited to, wood, metal, and plastics such as polyester, polyethylene, polyvinyl chloride, polypropylene, and combinations thereof.
[0040] In the embodiment depicted in Figures 1 to 7, panel 22 is square having first sides 40 approximately two feet in length and second sides 42 also approximately two feet in length. In this embodiment, the matrix of tubes 30 are arranged to define 2 columns and 12 rows of cavities adapted to accept plantings In this example, each tube will have an open end that measures approximately 2 inches by 12 inches, and have a depth of approximately 4 inches. Anchor layer 24 may have any dimensions suitable for a particular embodiment. In one embodiment, anchor layer 24 is between 0.125 and 1 inch thick. It will be appreciated by one skilled in the art that the precise dimensions of the vertical plant support 10 will be governed by many factors, including the location of the installation, tne types of plants grown, the weight-bearing capacity of any underlying support wall Modifications of this nature are intended to be included within the scope of this disclosure.
[0041] A further aspect illustrated in Figures 1 to 7 in respect to the vertical plant support 10 is the acute angle at which each tube in the matrix of tubes 30 extends outwardly from the anchor layer 24. In the depicted embodiment, each tube forms an approximately 60-degree angle with the anchor layer 24 Angles greater or less than 60 degrees may be employed as determined by the circumstances of the installation The purpose of the angle is to facilitate the retention of water and growth media that may be added to the closed cavity defined by each tube in the matrix of tubes 30.
(0042] In use, anchor layer 24 provides a means for supporting the growth of vegetation. Typically, the roots of vegetation propagate into, and become entangled in, anchor fayer 24. In this way, anchor layer 24 provides physical support to the vegetation. Anchor layer 24 also retains water and nutrients that are supplied to it and in turn supplies the water and nutrients to the vegetation. Anchor layer 24 may also be impregnated with a growth medium or growth medium may be added to the cavity defined by each tube in the matrix of tubes 30. Growth medium may be chosen from a variety of materials. For example, many soils, sands, and gravels may be used. As well, clay, gravel, fertilizer, peat, compost, super-absorbent polymers, and combinations thereof may be used in other embodiments, for example.
[0043] For greater certainty, examples of alternate embodiments of the vertical plant support are shown in Figures 8 to 10. Figure 8 shows vertical plant support 10' having a matrix of tubes 30' arranged as a single array of one column and 8 rows of tubes, with the open end of each tube measuring approximately 8 inches by 3 inches. Figure 9 shows a vertical plant support 10" similar to vertical plant support 10 with two columns and 9 rows qf tubes in the matrix 30" Similarly, Figure 10 shows an expanded vertical plant support 10"' having a matrix of tubes arranged into 9 rows and 8 columns. [0044] Referring now to Figure 11 , installations of a living wall 100 in accordance with the present invention may be accomplished by combining one αr more individual vertical plant supports 10. In the illustrated example, 12 vertical plant supports 10 are arranged in a four-by-three grid. Preferably, vertical plant supports 10 are shaped so as to abut with adjacent vertical plant supports so that little or no gaps are present, thereby enhancing the appearance of the living wall 100.
[0045] Referring to Figure 12, vertical plant support may optionally be adapted to interconnect with adjacent vertical wall supports 10 in a living wall 100 application Integral connectors may take on many different forms Figure 12 illustrates one such method, where at least one dovetail slot 110 is defined on an exterior surface 112 of the matrix of tubes 30 The opposite
exterior surface of the matrix of tubes 30 contains a similar number of dovetail nbs 120 positioned so as to align with the correspondingly sized dovetail slots 110 of an adjacent vertical plant support 10.
[0046] Individual vertical plant supports 10 can be located in indoor or outdoor environments, and may be connected to any number of different vertical support structures by numerous means within the skilf of an ordinary worker. A first example is illustrated in Figure 13, whereby one or more vertical plant supports can be hung from one or more beveled horizontal rails 130. Horizontal rails 130 may optionally be attached to vertical rails 132 to provide adequate clearance with the underlying support structure The horizontal rails 130 may also be connected directly to the surface of a structural wall 140 The blow-up detail of Figure 13 shows a side view of a vertical plant support 10 mounted on a horizontal rail 130 Horizontal rail 130 is advantageously configured to have a beveled top surface 134 that extends outwardly and upwardly with respect to the structural wall 140. Horizontal rails 130 may be connected to the structural wall 140 by many means commonly understood in (he art. The illustrated embodiment shows bolt 142 and spacers 138 located intermediate the horizontal rail 130 and the structural wall 140 The beveled angle on the horizontal rail 130 is adapted to match the angle of the hanging surface 52 of the example hanging element 50
[0047] Preferably, the angle of the matrix of tubes 30, the angle of the hanging surface 52, and the angle of the beveled upper surface of the horizontal are substantially equal with respect to the supporting structure such as structural wall 140 This allows an individual vertical plant support 10 that is a part of a larger living wall 100 installation, with adjacent vertical plant supports 10 abutting each other, to be slidably removed from living wall 100 for replacement with a new vertical plant support 10, or repair of the supporting structure such as the structural wall 140.
[0048] Figure 14 illustrates yet another example of a means for attaching vertical plant support 10 to its support structure. One or more hooks
150 may be connected to a ceiling, bracket or other weight-bearing structure
(not shown). One or more of the tubes in the matrix of tubes 30 may optionally define apertures 152 sized to accommodate hooks 150 Similarly, one or more of the tubes in the matrix of tubes 30 may optionally have a strap 154 connected thereto and of sufficient length to engage one or more hooks 150
[0049] With reference to Figure 15, there is shown an embodiment of an irrigation system for a vertical plant support 10. Water supply 160 is positioned along the upper surface of the matrix of tubes 30 and connected to a supply of water that may contain additional plant nutrients (not shown) The illustration shows water supply 160 as a soaker hose, but it will be appreciated that water supply 160 may include many other water distribution means such as drip irrigation or storm water runoff from a exterior roof. Preferable, water supply 160 is positioned so that the supplied water contacts (he upper surface 32 of the matrix of tubes 30 at or above upper edge 26 Water and/or nutrients may then flow downward under the influence of gravity, either directly onto the upper edge 26 of porous anchor layer 24 or down the inclined upper surface 32 of the matrix of tubes 30. Preferably, water supply 160 delivers the water to the vertical plant support 10 substantially as a sheet so that the volume of water entering the anchor layer 24 at its upper edge 26 is substantially uniform. Optionally, panel 22 my be extended upwardly or an additional barrier (not shown) may be attached to the upper edge of panel 22 to ensure that water or nutrients do not flow down the rear exterior surface of the panel 22, possibly causing damage to any supporting structural surfaces. Water and nutrients then flow downward through anchor layer 24 in main flow direction A. Optionally, a trough 170 may be positioned adjacent lower edge 28 to collect any discharge of excess water.
[0050] When vertical plant supports 10 are hung as part of a living wall
100 and at least one vertical plant support is mounted above another, it has been found to be advantageous if the lower edge 28 of the anchor layer 24 is positioned adjacent the upper surface 32 so that water and/or nutrients that dram from the upper vertical wall support 10 flow downward on the upper
surface in a manner similar to that described above. This positioning can be accomplished selectively sizing feet 54 or by any other means understood in the art.
[0051] Figure 16 illustrates that In additional to the main flow direction A, water and nutrients are able to drawn in wicking direction B by plants, either through wicking action or by saturating growth media that may be located in the cavities defined by each tube in the matrix of tubes 30 (not shown). Optionally, Figure 17 shows that mist irrigation systems may also be affixed to the front portion of the matrix of tubes, and arranges and operatsd as generally understood in the art.
[0052] Referring to Figure 18, there is shown an alternate embodiment of a vertical plant support 10"" for cleaning grey water. Preferably, defined in the horizontal surfaces of each tube in the matrix of tubes 30 there are flow holes 180 defined, spaced apart so as to form a boustrophedonic course C for the flow of grey water downward through the matrix of tubes 30 In this embodiment, vertical plant support 10"" may optionally contain one or more anchor layers 24 or other growth media as understood in the art.
[0053] Referring to Figure 19, optionally, a plurality of rooting holes 200 may be defined in the horizontal or vertical surfaces of each of the tubes in the matrix of tubes 30 to allow roots to grow between adjacent tubes in the matrix of tubes 30
[0054] Figure 20 illustrates another optional irrigation system wherein a pump 190 may be connected in fluid connection with trough 170. The outlet of pump 190 is then connected to conduit 192 for delivering water to the upper surface 32 of the matrix of tubes 30, above the upper edge 26, thereby creating a loop that recycles at least a portion of the water and/or nutrients
[0055] Vertical plant support 10 can be easily installed on-srte without requiring significant or permanent modification to the support structure or wall.
They may be hung from an existing structural wall or a support structure may be erected to support the vertical plant supports 10. This design feature
advantageously allows each vertical plant support 10 to be populated with plants off-site and in controlled conditions such as a plant nursery, and then transported to the installation location. Typically, one of the major risks and expense to installing a vertical plant support 10 or larger living wall 100 installations is the growing of the plants in what are sometimes marginal growing conditions. By growing and establishing the plants in controlled conditions, they are thereby better able to adapt to their installed environment with increased chance for successful growth. This also reduces expenses related to tending to the plants during the growing phase In this regard, the present invention also allows the vertical plant support 10 to be oriented horizontally while the plants are being established, which also facilitates the maintenance and increases the chances of successful growth during the initial phase.
[0056] This modularity also allows for individual vertical plant supports 10 to be exchanged as desired. Adjustments can therefore be made if the microclimate changes or if different plants are desired for a particular location One is also able to incorporate designs in a living wall 100 application by choosing plants desirable texture or colour characteristics in adjacent vertical plant supports 10. The design can then be changed later if desired. [0057] Optionally, vertical plant supports 10 may be used as part of a bio-filtration system In this case, panel 22 would be gas permeable, thereby allowing air to be forced through the vertical plant support 10 by establishing a pressure differential between the front and rear of the vertical plant supports 10 to draw air through the structure, thereby removing impurities from the air [0058] Figures 21 to 23 illustrate an alternate embodiment wherein the matrix of tubes 30 are manufactured using injection moulding, while panels 22 are stamped from sheets of suitable material
[0059] While the invention has been described with reference to specific embodiments, one skilled in the art will appreciate that various other adaptations and modifications may be made to the method and apparatus of
the present invention, and that ail such modifications and adaptations are intended to be encompassed within the scope of the invention.