Abstract
The invention discloses a stagger stacked flowerpot, which is characterized in that: the stagger stacked flowerpot is comprised of a flowerpot body, in which a soil baffle is provided to divide the flowerpot body into a plant and compost space and a water storage space; the soil baffle is provided with a water groove, which effectively separates the irrigated water from the soil. The invention has the advantages as simple structure, preferable rigidity, security, stability, reliability, convenient plantation, low construction and maintenance cost, fast irrigation and easy control thereof, and water-soil separation, and is suitable for building masonry walls, commercial spaces, residences and so on.
Claims
1. A stagger stacked flowerpot system, comprising: a plurality of flowerpot bodies (1) arranged in an array in a stagger way; wherein each of the plurality of flowerpot bodies (1) contains a seedling pot (7) or a soil baffle (2), each of the plurality of flowerpot bodies (1) including a cavity for receiving the seedling pot (7) or the soil baffle (2), a water storage space (16) formed at an inner bottom portion of the each of the plurality of flowerpot bodies (1), a snap groove (9) formed on a middle portion of an outside surface of the bottom of the each of the plurality of flowerpot bodies (1), the each of the plurality of flowerpot bodies (1) including a back planar portion abut against a wall and a front curve portion matching a shape of the seedling pot (7) or the soil baffle (2), the front curve portion having an curved upper edge, end portions of the curved upper edges between two adjacent flowerpot bodies forming a joint portion, the snap groove (9) formed on each flowerpot body arranged to clamp the joint portion, a drain hole (6) arranged at the bottom of the each of the plurality of flowerpot bodies (1) and arranged away from the middle portion of the bottom of the each of the plurality of flowerpot bodies (1), the drain hole (6) is as high as a maximum water level in the water storage space (6), and water in the water storage space (16) overflowing out from the drain hole (6) and then flowing into the water storage space of a flowerpot body (1) arranged at a lower level.
2. The stagger stacked flowerpot system according to claim 1, wherein a top part of each of the plurality of flowerpot bodies (1) projects out with a predefined angle such that a barycenter of the seedling pot (7) is within the range of a bottom diameter of the seedling pot (7).
3. The stagger stacked flowerpot system according to claim 1, further comprising a front bracing (4) and a rear bracing (5) arranged in the bottom portion of the each of the plurality of flowerpot bodies (1) to brace the seedling pot (7) or the soil baffle (2).
4. The stagger stacked flowerpot system according to claim 3, wherein a rear bracing sleeve (17) is arranged at the bottom of the soil baffle (2) and is sleeved on the rear bracing (5).
5. The stagger stacked flowerpot system according to claim 4, wherein after the rear bracing sleeve (17) is arranged in the each of the plurality of flowerpot bodies (1), the peripheral wall of the rear bracing sleeve fits in with the inner wall of the each of the plurality of flowerpot bodies (1); and the back wall of the rear bracing sleeve (17) partially warps up, so that the upwarped part and the inner wall of the each of the plurality of flowerpot bodies (1) jointly form a water groove (12), through which water flows into the water storage space (16).
Description
BRIEF DESCRIPTION OF ATTACHED DRAWINGS
(1) FIG. 1A is a stereo diagram for body of the stagger stacked flowerpot;
(2) FIG. 1B is the flowerpot side view of the stagger stacked flowerpot;
(3) FIG. 2 is the top view of the body of the stagger stacked flowerpot;
(4) FIG. 3 is the broken-out section view of the stagger stacked flowerpots;
(5) FIG. 4 is the schematic diagram for soil baffle of the stagger stacked flowerpot;
(6) FIG. 5 is the assembly diagram for soil baffle of the stagger stacked flowerpot;
(7) FIG. 6 is the assembly diagram for the seedling pot directly used for the stagger stacked flowerpot;
(8) FIG. 7A is the assembly diagram for the stereo greening wall space stacked by the stagger stacked flowerpots;
(9) FIG. 7B is the partial diagram of FIG. 7A;
(10) FIG. 8 is the diagram for the irrigation flowing direction after stacking of the stagger stacked flowerpots;
(11) FIG. 9 is the bottom structure diagram after stacking of the stagger stacked flowerpots;
(12) FIG. 10 is the direct water level diagram after stacking of the stagger stacked flowerpots;
(13) FIG. 11A is the adjustable water level diagram after stacking of the stagger stacked flowerpots;
(14) FIG. 11B is the sectional view of FIG. 11A;
(15) In the figures, 1flowerpot body; 2soil baffle; 3hanging hole; 4front bracing; 5rear bracing; 6drain hole; 7seedling pot; 8flowing direction; 9snap groove; 10top bracing edge; 11bracing position; 12water groove; 13locking port; 14post-irrigation water level; 15water-level control tube; 16water storage space; 17rear bracing sleeve; 18pervious hole; 19bottom hole; 20water-distributing pipe; 21effluent adjusting cock; 22seedling pot blocking position.
(16) Embodiments
(17) The preferable embodiments and relevant figures are provided in the following to make the invention more distinct and understandable.
(18) The invention refers to a stagger stacked flowerpot as shown in FIG. 1A and FIG. 1B, the stereo diagrams of the stagger stacked flowerpots. The invention comprises a flowerpot body 1 composed of three cavities, which are mutually connected and used to hold the seedling pot 7 or the soil baffle 2. The top part of each cavity leans out with the dip angle of , to ensure that the plant may grow outwards to gain more space and sunlight and the seedling pot 7 is not blown down by the wind, for the barycenter P of the seedling pot 7 in the cavity is within the range of the bottom diameter of the seedling pot 7. A hanging hole 3 is arranged on the back of the flowerpot body 1 and can be used to mount the flowerpot body onto the back wall or grid frame conveniently. A snap groove 9 is provided at the bottom of the flowerpot body 1 and a top bracing edge 10 and a bracing position 11 are arranged at the top of the flowerpot body and can be mutually locked when the flowerpots are stacked, to improve the integral rigidity of the greening wall space.
(19) FIG. 2 presents a top view of the body of the stagger stacked flowerpots. The front bracing 4 and rear bracing 5 are provided in the flowerpot body 1 and used to hold the soil baffle 2 or seedling pot 7, which form the water storage spaces 16 with the bottom cavities of the flowerpot body 1 and are connected with each other. The drain hole 6 with the opening upward is provided in the flowerpot body 1. When the water in the water storage space 16 rises to the level of the opening of the drain hole 6, excess water may flow through the drain hole 6 down to the flowerpots of the lower layer.
(20) FIG. 3 is a partial sectional stereogram for the stagger stacked flowerpot, of which the water storage space 16 is lower than and connected with the drain hole 6.
(21) FIG. 4 is the diagram for the soil baffle 1 of the stagger stacked flowerpot. The soil baffle 2 is dimensionally identical to the inner cavity of the flowerpot body 1 and the water groove 12 is provided so that the overflowing water from the top layer does not directly fall onto the soil, so that the survival rate of the plants can be improved and soil loss is reduced. In addition, the rear bracing sleeve 17 and pervious hole 18 are provided to ensure that some water of the water storage space 16 seeps through the soil.
(22) FIG. 5 is a partial sectional stereogram after the assembly of the stagger-stacked flowerpot body and the soil baffle. The rear bracing sleeve 17 is sleeved into the rear bracing 5, the horizontal position of the pervious hole 18 is lower than the drain hole 6, and the edges of the pervious hole 18 contact with the front bracing 4.
(23) FIG. 6 is the diagram for the seedling pot used for a stagger stacked flowerpot. The bottom of the seedling pot 7 contacts with the rear bracing 5 and the front bracing 4, and the level position of the bottom hole 9 of the seedling pot 7 is lower than the drain hole 6, so that water of the water storage space seeps through the soil.
(24) FIG. 7 is an assembly diagram for the stereo greening wall space stacked with stagger stacked flowerpots. The flowerpot bodies 1 can be stacked and combined to form a stereo greening wall space, which is comprised of two or more vertically stacked flowerpot bodies 1. After vertical stagger stacking, the snap groove 9 at the bottom of the upper flowerpot body 1 is firmly snapped to and mutually connected with the bracing edge 10 and bracing position 11 at the top of the lower flowerpot body 1 to improve integral rigidity of the stereo greening wall space.
(25) FIG. 8 is the diagram for the irrigation flowing direction after stacking of a stagger stacked flowerpot. After the flowerpot bodies 1 are combined to form a greening wall, the water-distributing pipe 20 is mounted on the top layer of the flowerpots and connected with the effluent adjusting cock 21. When the soil baffle 2 is used, the flowing direction 8 may continue along the water groove 12 to the water storage space 16 at the bottom of the flowerpot body 1; when the seedling pot 7 is used, the flowing direction 8 may go along the outer wall of the seedling pot into the water storage space 16 at the bottom of the flowerpot body 1. After the post-irrigation water level 14 is up to the level of the drain hole 6, water may flow along the drain hole 6 into the flowerpot body 1 of the lower layer, until the bottom layer is irrigated by analogy. The irrigation method is bottom self-absorbing and overcomes easy clogging of the trickle irrigator and high construction and maintenance costs encountered by the trickle irrigation method.
(26) FIG. 9 is the bottom structure diagram after stacking of a stagger stacked flowerpot. When the seedling pot after stacking is directly used for plantation, the locking ports 13 of the upper flowerpots are used to clamp the blocking position 22 of the seedling pot 7, so that the seedling pot cannot escape outwards naturally, to largely improve the security of external wall plantation of high-rise buildings.
(27) FIG. 10 is the diagram for water level of direct utilization of a stagger stacked flowerpot stacked. When the stagger stacked flowerpots are used directly after stacking, the post-irrigation water level 14 can rise to the height h1 of the drain hole 6 and is suitable to plant the plants requiring less water.
(28) FIG. 11A and FIG. 11B are the adjustable water level diagram after stacking of the stagger stacked flowerpots. When the plants require more water, the water-level control tube 15 can be sleeved to the drain hole 6 as per relevant height, the post-irrigation water level 14 can reach the height h2 (greater than h1) of the adjustable water pipe 14, so that the storage water level is advanced and more water can be provided to seep the soil and satisfy the plants requiring more water. The length of the water-level control tube can be adjusted according to water demand of the plants.
