Stackable Modular Planter

Abstract

A stackable modular planter includes an open top plant box with a base and four side walls adapted to receive a growing medium and plants. The open top plant box has a first width. An irrigation box below the open top plant box base has a second width larger than the first width. The irrigation box can be filled with irrigation fluid. An open top hopper on one side of the open top plant box on top of the irrigation box can receive irrigation fluid which drains into the irrigation box. An overflow drain aperture in the irrigation box lets excess irrigation fluid flow. When a plurality of the stackable modular planters are stacked above another planter, excess irrigation can flow from the overflow aperture into the hopper of the planter below.

Description

FIELD

The present invention relates to a modular stackable planter.

BRIEF SUMMARY

According to the present invention there is provided a stackable modular planter comprising:

a) an open top plant box having a base and four side walls adapted to receive a growing medium and plants, said open top box having a first width,

b) an irrigation box below the open top box base having a second width larger than the top box first width, said irrigation box adapted to be filled with irrigation fluid,

c) an open top hopper on one side of the open top box on top of the irrigation box adapted to receive irrigation fluid which drains into the irrigation box,

d) an overflow drain aperture in the irrigation box through which excess irrigation fluid can flow, and

e) means to stack one planter above another planter,

in use, when one planter is stacked above another planter, excess irrigation can flow from the overflow aperture into the hopper of the planter below.

Preferably the width of the open top box and the hopper is substantially equal to the width of the irrigation box.

Preferably the depth of the irrigation box is less than the depth of the open top box whereby a plant growing from the open top of a planter below can pass in front of an irrigation box of a planter above. Preferably the front side wall of the open top box is tapered inwards from the top face of the box to the irrigation box. Preferably the top edge of a front wall of the open top box is lower than the top edge of a rear wall of the open top box. Preferably the rear face of the open top box is substantially planer with the rear face of the irrigation box.

Preferably frames are provided either side of the planter, said frames providing means to allow one planter to stack above another planter. Preferably the frames include projections to engage in recesses of an adjacent frame on another planter.

Preferably clips are provided to connect single stacked planters in side by side relationship. The clips may connect the frame on one planter to the frame of another adjacent planter.

In one embodiment the top open face plant box and irrigation box are formed from a master open top faced box with a floor between the top open face and the bottom of the master open box to create an upper open top plant box and a lower irrigation box, said hopper being provided between one end of the master open box and a partition spaced from said one end of the master open box and extending up from the floor, said plant box being formed between the partition and the other end of the master open box and the floor. Preferably the floor extends between said other end of the open box and the partition leaving an aperture between the bottom of the hopper and the top of the irrigation box through which irrigation fluid can pass.

Preferably opposing side walls of the master box taper inwards. Preferably one side wall includes an aperture forming said overflow drain aperture. Preferably a side frame cooperates with said one side wall to create a channel to direct irrigation fluid into the hopper of a planter stacked below.

Preferably the hopper includes a removable funnel section with a filter at its opening to allow any growing medium or plant debris to be cleaned away from the hopper.

Preferably a gauge is provided to determine the level of irrigation fluid in the irrigation box. The gauge may be float controlled.

Preferably one or more apertures are provided between the plant box and the irrigation box to receive one or more wicks to feed irrigation fluid to growing medium in the plant box.

BRIEF DESCRIPTION OF THE DRAWINGS

An embodiment of the invention will now be described with reference to the accompanying drawings in which:

FIG. 1 shows a perspective view of a planter,

FIG. 2 shows a perspective view of a pair of planters stacked one above the other,

FIG. 3 shows an exploded view of the planter of FIG. 1,

FIG. 4 shows a cross section view showing the overflow aperture and filling of the irrigation box, and

FIG. 5 shows a cross section of the planter with a wick.

DESCRIPTION OF EXAMPLE EMBODIMENT

Referring to FIGS. 1 and 2 of the drawings there is shown a stackable modular planter 1. Planter 1 has an open top plant box 10 having a base 11 and two opposing side walls 12,13 and a front and rear side wall 14,15. The top face 16 of box 10 is open. Top plant box 10 is adapted to receive a growing medium and plants. Open top box has a first width “A”. Front side wall 14 is tapered inwards from the top face of the box to an irrigation box 20 (see below).

An irrigation box 20 is provided below the open top box 10 base having a second width “B” larger than the top box first width “A”. Irrigation box 20 is adapted to be filled with irrigation fluid. Box 20 has a front wall 21, side walls 22,23 and a rear wall 24, and a sealed base 25.

The depth of the irrigation box 20 is less than the depth of the open top box whereby a plant “P” growing from the open top 16 of a planter below can pass in front of an irrigation box front wall 20 of a planter above (see FIG. 2). To further facilitate this, the top edge of the front wall 14 of the open top box is lower than the top edge of a rear wall 15 of the open top box. The rear face 15 of the open top box is substantially planer with the rear wall 24 of the irrigation box 20.

An open top hopper 30 is on one side of the open top box 10 on top of the irrigation box 20 adapted to receive irrigation fluid. Preferably the width of the open top box 10 and the hopper 30 is substantially equal to the width of the irrigation box 20, so that fluid in the hopper drains into the irrigation box 20 immediately below. Hopper is used to fill the irrigation box 20, e.g. using a watering can or water pipe nozzle.

As shown in FIG. 3, it is preferred that the top open face plant box 10 and irrigation box 20 are formed from a master open top faced box 40 with a floor 41 between the top open face and the bottom of the master open box to create an upper open top plant box and a lower irrigation box, said hopper 30 being provided between one end 42 of the master open box and a partition 43 spaced from said one end of the master open box and extending up from the floor 41. The plant box 10 is thus formed between the partition 43 and the other end 44 of the master open box and the floor. Preferably the floor 41 extends between said other end 44 of the master open box and the partition 43 leaving an aperture 45 between the bottom of the hopper and the top of the irrigation box through which irrigation fluid can pass. Preferably opposing side walls 42,44 of the master box taper inwards toward the bottom of the master box.

A pair of frames 50A,50B are provided either side of the planter 1, said frames providing means to allow one planter to stack above another planter. The frames include projections 51 to engage in recesses 52 of an adjacent frame on another planter.

Preferably clips are also provided (not shown) to connect single stacked planters in side by side relationship. The clips may connect the frame on one planter to the frame of another adjacent planter. The frames 50A,50B provide means to stack one planter above another planter.

An overflow drain aperture 60 is provided in the irrigation box through which excess irrigation fluid can flow. The drain aperture is provided in side wall 42 of master box 40 (side wall 22 of irrigation box 20). Frame 50A has opposing walls 53A,53B which cooperate with side wall 42 (side wall 22 of irrigation box 20) to create a channel to direct irrigation fluid into the hopper of a planter stacked below (see arrow). Thus in use, when one planter is stacked above another planter, excess irrigation can flow from the overflow aperture can flow into the hopper of the planter below.

Preferably one or more apertures 46 are provided in floor 41 between the plant box and the irrigation box to receive one or more wicks 60 to feed by capillary action irrigation fluid to growing medium in the plant box.

Preferably a gauge 70 is provided to determine the level of irrigation fluid in the irrigation box. The gauge may be float controlled.

Preferably the hopper 30 includes a removable funnel section 31 with a filter 32 (see FIG. 4)) to allow any growing medium or plant debris to be cleaned away from the hopper. When planting the planter or removing plants there is a tendency for growing medium (e.g. soil) to fall into the hopper is the funnel section 31 is not in situ. Funnel section 31 may have a hole 33 leading to the filter which then leaks irrigation fluid into the hopper. Funnel section 31 is removable to allow it and its filter 32 to be cleaned. This keeps the irrigation box clean of debris.

It is envisaged that user can purchase a number of planters stacking them both vertically and in side by side relationship to create a desired area for growing plants. The planters may be stacked several high and be free standing, but if desired fixings in cut-outs 80 (see FIG. 1) can be used to secure them to a vertical surface for greater structural strength.

The invention may take a form different that specifically described. For example the top plant box 10, irrigation box 20 and hopper 30 could be three separate components joined together rather than being formed from a master box 40 as shown in FIG. 3.

Further modifications will be apparent to those skilled in the art without departing from the scope of the present invention.

Claims

1-19. (canceled)

20. A stackable modular planter comprising: a) an open top plant box having a base and four side walls adapted to receive a growing medium and plants, said open top plant box having a first width,b) an irrigation box below the open top plant box base and having a second width larger than the first width, said irrigation box adapted to be filled with irrigation fluid,c) an open top hopper on one side of the open top plant box on top of the irrigation box, the open top hopper adapted to receive irrigation fluid which drains into the irrigation box,d) an overflow drain aperture in the irrigation box through which excess irrigation fluid can flow, ande) means to stack one stackable modular planter above another stackable modular planter,

21. The stackable modular planter of claim 20, wherein the first width of the open top plant box and a width of the open top hopper is substantially equal to the second width.

22. The stackable modular planter of claim 20, wherein a depth of the irrigation box is less than a depth of the open top plant box whereby a plant growing from the open top plant box of a stackable modular planter below can pass in front of an irrigation box of a stackable modular planter above.

23. The stackable modular planter of claim 20, wherein a front side wall of the open top plant box is tapered inwards from a top face of the open top plant box to the irrigation box.

24. The stackable modular planter of claim 20, wherein a top edge of a front wall of the open top plant box is lower than a top edge of a rear wall of the open top plant box.

25. The stackable modular planter of claim 20, wherein a rear face of the open top plant box is substantially planer with a rear face of the irrigation box.

26. The stackable modular planter of claim 20, wherein frames are provided either side of the stackable modular planter, said frames providing means to allow one stackable modular planter to stack above another stackable modular planter.

27. The stackable modular planter of claim 26, wherein the frames include projections to engage in recesses of an adjacent frame on another stackable modular planter.

28. The stackable modular planter of claim 20, wherein clips are provided to connect single stacks of stackable modular planters in side by side relationship.

29. The stackable modular planter of claim 28, wherein the clips connect a frame on one stackable modular planter to a frame of another adjacent stackable modular planter.

30. The stackable modular planter of claim 20, wherein the open top plant box and irrigation box are formed from a master open top faced box with a floor between a top open face and a bottom of the master open top faced box to create an upper open top plant box and a lower irrigation box, said open top hopper being provided between one end of the master open top faced box and a partition spaced from said one end of the master open top faced box and extending up from the floor, said open top plant box being formed between the partition and the other end of the master open top faced box and the floor.

31. The stackable modular planter of claim 30, wherein the floor extends between said other end of the open top plant box and the partition leaving an aperture between a bottom of the open top hopper and a top of the irrigation box through which irrigation fluid can pass.

32. The stackable modular planter of claim 30, wherein opposing side walls of the master open top faced box taper inwards.

33. The stackable modular planter of claim 30, wherein one side wall includes an aperture forming said overflow drain aperture.

34. The stackable modular planter of claim 33, wherein frames are provided either side of the stackable modular planter, said frames providing means to allow one stackable modular planter to stack above another stackable modular planter, and a side frame cooperates with said one side wall to create a channel to direct irrigation fluid into the open top hopper of a stackable modular planter stacked below another stackable modular planter.

35. The stackable modular planter of claim 20, wherein the open top hopper includes a removable funnel section with a filter at its opening to allow any growing medium or plant debris to be cleaned away from the open top hopper.

36. The stackable modular planter of claim 20, wherein a gauge is provided to determine a level of irrigation fluid in the irrigation box.

37. The stackable modular planter of claim 36, wherein the gauge is float controlled.

38. The stackable modular planter of claim 20, wherein one or more wick apertures are provided between the open top plant box and the irrigation box to receive one or more wicks to feed irrigation fluid to the growing medium in the open top plant box.