CN217117172U - Tidal water planting pot and stereoscopic planting device - Google Patents

Abstract

The utility model provides a basin is planted to morning and evening tides water planting, include: the flowerpot comprises a flowerpot body, a water inlet and a water outlet, wherein the flowerpot body is provided with a water outlet hole, the side wall of the flowerpot body is provided with a first conical groove and a second conical groove, the first conical groove and the second conical groove are alternately distributed along the circumferential direction of the flowerpot body, and the taper of the first conical groove is larger than that of the second conical groove; a planting cup which is fixed on the outer wall of the pot body and is communicated with the pot body. The embodiment also provides a stereoscopic planting device, which comprises a base; the tidal water planting pots are distributed in a stacked mode from bottom to top, and in two adjacent tidal water planting pots, the bottom of a first conical groove of an upper tidal water planting pot is embedded into the top of a second conical groove of a lower tidal water planting pot; and a nutrient solution circulating device. The utility model discloses can assemble in a flexible way, conveniently plant the equipment of basin and accomodate, can alternate planting device's form as required.

Description

Tidal water planting pot and stereoscopic planting device

Technical Field

The utility model relates to a plant technical field particularly, relate to a basin and three-dimensional planting device are planted to morning and evening tides water planting.

Background

The three-dimensional planting has the characteristics of small occupied area, high unit area yield, various forms, convenience in management and the like, is a trend of modern urban agriculture development, and is particularly suitable for indoor, balcony, roof and other spaces for green planting of vegetables and flowers by urban residents. However, the existing stereoscopic planting device has the defects of single function, inflexible assembly and use, rigid and unattractive shape, inapplicability to planting with developed root systems or plants with large plant quality and the like, so that the popularization and the application of the stereoscopic planting in cities are limited.

However, the existing three-dimensional cultivation device is not flexible in assembly and inconvenient for plant cultivation and replacement.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a basin is planted to morning and evening tides water planting, it designs to planting the basin, can assemble in a flexible way, conveniently plants the equipment of basin and accomodate.

Another object of the utility model is to provide a stereoscopic planting device, it designs to stereoscopic planting device, can assemble in a flexible way, can alternate planting device's form as required.

The embodiment of the utility model discloses a realize through following technical scheme:

tidal hydroponic planting basin, it includes: the flowerpot comprises a flowerpot body, a water outlet hole is formed in the flowerpot body, a first conical groove and a second conical groove are formed in the side wall of the flowerpot body, the first conical groove and the second conical groove are alternately distributed along the circumferential direction of the flowerpot body, and the taper of the first conical groove is larger than that of the second conical groove; the planting cup is fixed on the outer wall of the pot body and communicated with the pot body.

In an embodiment of the present invention, the bottom of the planting cup is provided with a storage tank, and the storage tank is located below the communicating portion of the planting cup and the basin body.

In an embodiment of the present invention, the side wall of the basin body is inclined from bottom to top to the outside of the basin.

In an embodiment of the present invention, the drain hole includes a low water level drain hole and a high water level drain hole, and a diameter of the low water level drain hole is smaller than a diameter of the high water level drain hole.

The utility model discloses an in the embodiment, basin body bottom is equipped with one-level round platform and second grade round platform, and this one-level round platform is located second grade round platform bottom, this one-level round platform is located to low water level wash port, and this high water level wash port is located this second grade round platform.

The stereoscopic planting device comprises a base; the tidal water planting pots are distributed in a stacked mode from bottom to top, the tidal water planting pot located on the bottommost layer is arranged on the base, and in two adjacent tidal water planting pots, the bottom of a first conical groove of the upper tidal water planting pot is embedded into the top of a second conical groove of the lower tidal water planting pot; and a nutrient solution circulating device for supplying nutrient solution to the tidal hydroponic planting pot.

The utility model discloses an in the embodiment, nutrient solution circulating device includes water tank, feed pipe and water pump, and the end of intaking of this water pump communicates with this water tank, and the play water end and this feed pipe intercommunication of this water pump, and the confession liquid of this feed pipe to the highest layer the basin is planted to morning and evening tides water planting.

In an embodiment of the utility model, a plurality of the tidal water planting pot cover is located the liquid supply pipe.

The utility model discloses an in one embodiment, the water tank is located in the base, the feed pipe communicates with this water tank, and is located the bottom the basin is planted to morning and evening tides water planting communicates with the water tank.

The utility model discloses technical scheme has following advantage and beneficial effect at least:

the embodiment of the utility model arranges the planting cup communicated with the pot body outside the planting pot to plant the plants in the planting cup, a first conical groove and a second conical groove with different conicity are arranged on the side wall of the pot body, for two vertically adjacent pot bodies, when the first conical groove of the upper pot body is inserted into the first conical groove of the lower pot body and the second conical groove of the upper pot body is inserted into the second conical groove of the lower pot body, the upper pot body can be inserted into the lower pot body to realize the storage of the planting pot, when the first conical groove of the upper pot body is inserted into the second conical groove of the lower pot body, and the second conical groove of the upper pot body is inserted into the first conical groove of the lower pot body, the upper pot body can only be partially inserted into the lower pot body, and the lower pot body supports the upper pot body, so that the planting device can be flexibly assembled, and the shape of the planting device can be changed as required.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a schematic view of a first structure of a tidal hydroponic culture pot according to the present invention;

FIG. 2 is a front view of FIG. 1;

FIG. 3 is a second structural diagram of the tidal hydroponic culture pot of the present invention;

FIG. 4 is a front view of FIG. 3;

FIG. 5 is a schematic structural view of the middle-sized planting device of the present invention;

FIG. 6 is a schematic view of the assembly of the liquid supply tube and the planting pot;

fig. 7 is the assembly schematic diagram of the planting pot and the water tank, the water tank and the water pump of the utility model.

Icon: 1-planting pot, 11-pot body, 111-first conical groove, 112-second conical groove, 113-low water level drainage hole, 114-high water level drainage hole, 115-first-stage circular table, 116-second-stage circular table, 12-planting cup, 121-containing groove, 2-base, 31-water tank, 32-liquid supply pipe, 33-water pump and 34-water level sensor.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention, as generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the invention, as presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

In the description of the present invention, it should be noted that if the directions or positional relationships indicated by the terms "inside" and "outside" are based on the directions or positional relationships shown in the drawings, or the directions or positional relationships that the products of the present invention are usually placed when used, the description is only for convenience of description and simplification, but the indication or suggestion that the indicated device or element must have a specific direction, be constructed and operated in a specific direction, and therefore, should not be interpreted as a limitation of the present invention.

In the description of the present invention, it should be further noted that unless otherwise explicitly stated or limited, the terms "disposed," "mounted," "configured," and "connected" should be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1

Referring to fig. 1 to 4, the present embodiment provides a tidal hydroponic planting pot, which includes a pot body 11 and a planting cup 12.

Referring to fig. 1, the sidewall of the tub body 11 is provided with an embedded support portion, which may be a slot disposed at the tub opening, and the embedded support portion may be another structure capable of embedding the bottom of another planting tub 1 and providing support for stacking the two.

Referring to fig. 5 to 7, when a plurality of planting pots 1 need to be stored, two adjacent planting pots 1 are stacked, the first conical grooves 111 of the two planting pots are correspondingly embedded into the first conical grooves 111, the second conical grooves 112 of the two planting pots are correspondingly embedded into the second conical grooves 112, and one planting pot 1 can accommodate another planting pot 1, so that the space occupied by the planting pots 1 is reduced, the storage of the planting pots is realized, and the carrying is convenient.

When a planting device is required to be built by using the planting pots 1, the planting pots 1 are stacked from bottom to top, for two adjacent planting pots 1, the first conical groove 111 of the upper planting pot 1 is embedded into the second conical groove 112 of the lower planting pot 1, the second conical groove 112 of the upper planting pot 1 is embedded into the first conical groove 111 of the lower planting pot 1, because the taper of the first conical groove 111 is larger than that of the second conical groove 112, so that the upper planting pot 1 can not be completely embedded into the lower planting pot 1, and can only be embedded into the lower planting pot 1 by a set depth, if the planting pots are embedded for 5-7cm and the like, a space for containing nutrient solution is reserved in the planting pots 1 below, the planting pots 1 above can also be supported, a person skilled in the art can stack any number of planting pots 1 to build the planting device, and the flexible assembly of the planting device is realized.

The conical groove design in this embodiment has the following functions: firstly, in the packaging and transportation process of the planting pot 1, the conical design can be that the planting pot 1 is closely matched up and down and stacked, so that the packaging space and the transportation space are saved, and the packaging and transportation cost is greatly reduced; secondly, a user uses the planting pots 1 to carry out building block type assembly, conical grooves of the upper layer of planting pots 1 and the lower layer of planting pots 1 are installed in a staggered matching mode, namely the first conical groove 111 and the second conical groove 112 on the upper layer are correspondingly stacked and installed, when the two planting pots 1 are overlapped and stacked to a certain depth, the first conical groove 111 plays a supporting role for the upper layer of planting pots 1, and therefore a plant root system production space and a nutrient solution reservoir are formed inside the lower layer of planting pots 1; thirdly, the built three-dimensional planting system is installed in a mode that conical grooves of upper and lower planting pots 1 are installed in a staggered and matched mode, the first conical grooves 111 and the second conical grooves 112 are matched to generate gaps on the overlapped surfaces of the two planting pots, air holes of the planting pots are formed, the respiration of plant roots is facilitated, and the plants grow fast.

It should be noted that, referring to fig. 1, the side wall of the pot body 11 is inclined from bottom to top to the outside of the pot so that the planting pots 1 are stacked when being stored. When the side wall of the pot body 11 is in a right-angle relationship with the pot bottom, in order to realize the stacking of the planting pots 1, the pot bodies 11 of two adjacent planting pots 1 need to satisfy the condition of one large pot and one small pot.

Referring to fig. 1 to 4, the planting cup 12 is fixed on the outer wall of the pot body 11 and is communicated with the pot body 11, a containing groove 121 is arranged at the bottom of the planting cup 12, and the containing groove 121 is positioned below the communicating part of the planting cup 12 and the pot body 11. The plants to be planted are planted in the containing groove 121 of the planting cup 12, planting matrix can be placed in the planting cup 12, and the planting cup 12 is located outside the pot body 11. And the plant is placed in storage tank 121, and in morning and evening type cultivation, when the nutrient solution rises tide, nutrient solution overflows to planting cup 12 from basin body 11 to the gathering is in storage tank 121, until storage tank 121 is full of nutrient solution, after the nutrient solution subsides tide, the nutrient solution in the basin body 11 flows out gradually, and the nutrient solution that is detained in storage tank 121 at this moment can supply the plant to utilize, with the guarantee plant to grow.

It should be noted that, according to the number of the planting cups 12, the planting pots 1 can be divided into a single planting cup planting pot, a double planting cup planting pot, three planting cup planting pots, four planting cup planting pots, and the like. Plant basin 1 can be like taking building blocks, carry out perpendicular range upon range of equipment with a plurality of planting basins 1, combine according to customer hobby, scene demand, plant collocation, form the three-dimensional planting form of the different patterns of different height, the skilled person in the art can plant the basin with single planting cup, two planting cups plant the basin, three kinds plant the cup and plant the basin, four kinds plant nimble collocation equipment such as cup planting basin, can alternate planting device's form according to user's needs to obtain the nimble pleasing to the eye planting device of form.

Referring to fig. 1 to 4, the bottom of the tub 11 is provided with drain holes, in order to be suitable for tidal cultivation, the drain holes include a low water level drain hole 113 and a high water level drain hole 114, the bottom of the tub 11 is provided with a first-stage circular table 115 and a second-stage circular table 116, the first-stage circular table 115 is located at the bottom of the second-stage circular table 116, the low water level drain hole 113 is located on the first-stage circular table 115, the high water level drain hole 114 is located on the second-stage circular table 116, and the hole diameter of the low water level drain hole 113 is smaller than that of the high water level drain hole 114. In the morning and evening tides formula cultivation, when the nutrient solution rises tide, the nutrient solution in the basin body 11 increases gradually, the liquid level risees gradually, when the nutrient solution liquid level risees to one-level step, partial nutrient solution flows out the basin body 11 from low water level wash port 113, nutrient solution inflow rate in the basin body 11 this moment is greater than the outflow, when the nutrient solution liquid level risees to second grade step, partial nutrient solution flows out the basin body 11 from high water level wash port 114, nutrient solution inflow rate in the basin body 11 this moment equals the outflow to ensure that the nutrient solution maintenance liquid level in the basin body 11 is held at the settlement position. When the nutrient solution goes down, the liquid level of the nutrient solution flows from the second step to the first step, and finally flows out of the pot body 11 through the low-water-level water discharge hole 113.

It should be noted that the bottom of the basin 11 is also provided with a central hole for inserting the liquid supply tube 32.

Example 2

Referring to fig. 5 to 7, the present embodiment provides a three-dimensional planting device, which includes a base 2, a plurality of tidal hydroponic planting pots 1, and a nutrient solution circulation device.

Referring to fig. 5 to 7, a plurality of tidal hydroponic planting pots 1 are stacked from bottom to top, and in two adjacent tidal hydroponic planting pots 1, the bottom of the upper tidal hydroponic planting pot 1 is embedded in the embedded support portion of the lower tidal hydroponic planting pot 1, specifically, the first conical groove 111 of the upper planting pot 1 is embedded in the second conical groove 112 of the lower planting pot 1, and the second conical groove 112 of the upper planting pot 1 is embedded in the first conical groove 111 of the lower planting pot 1, because the conicity of the first conical groove 111 is greater than that of the second conical groove 112. And in all the tidal hydroponic planting pots 1, the tidal hydroponic planting pot 1 located at the bottommost layer is placed or fixed on the base 2. In this embodiment, base 2 is water tank 31 promptly, can understand that water tank 31 has base 2's effect concurrently, consequently, 31 tops of water tank are equipped with the jack, lie in this jack of the morning and evening tides water planting basin 1 embedding of bottommost layer to realize fixedly, and communicate with water tank 31.

Referring to fig. 6 to 7, the nutrient solution circulation device is used to supply nutrient solution to the tidal hydroponic planting pot 1. The nutrient solution circulation device includes a water tank 31, a liquid supply pipe 32, a water pump 33, and a control system (not shown). The water tank 31 can be independently arranged, the water tank 31 can also be arranged in the base 2, and the water tank 31 is arranged in the base 2 in the embodiment, namely, the water tank 31 has the function of the base 2. Since the weight of all the tidal hydroponic culture pots 1 is borne by the water tank 31, a skeleton or other structures for improving strength are correspondingly arranged in the water tank 31.

The water pump 33 is used for pumping nutrient solution in the water tank 31 to the tide water planting pot 1, the water pump 33 can be arranged outside the water tank 31 and communicated with the water tank 31 through a pipeline, and the water pump 33 can also be arranged in the water tank 31, for example, a miniature submersible pump and the like are adopted. The lower extreme of feed pipe 32 communicates with the play water end of water pump 33, and the upper end of feed pipe 32 and the tidal water planting of highest floor plant basin 1, promptly, water pump 33 supplies the nutrient solution in water tank 31 for the tidal water planting of highest floor earlier and plants basin 1, and the nutrient solution flows downwards from the tidal water planting of highest floor plant basin 1 layer by layer again, because the tidal water planting of bottommost layer plants basin 1 and water tank 31 intercommunication, so the nutrient solution finally flows down back in the water tank 31 to realize the circulation of nutrient solution. It should be noted that the liquid supply pipe 32 may be provided outside the tidal hydroponic planting basin 1, and the liquid supply pipe 32 may also be provided inside the tidal hydroponic planting basin 1, in this example, the liquid supply pipe 32 is provided inside the tidal hydroponic planting basin 1, that is, please refer to fig. 6 and fig. 7, the bottom of the basin body 11 of the tidal hydroponic planting basin 1 is provided with a central hole, and after all the tidal hydroponic planting basins 1 are stacked in sequence, starting from the lowest tidal hydroponic planting basin 1, the liquid supply pipe 32 sequentially passes through the central holes of the basin bodies 11 until reaching the highest tidal hydroponic planting basin 1.

This embodiment will plant the range upon range of setting of misplacing about 1 basin, and the bottom of planting basin 1 on the upper strata overlaps embedding lower floor and plants basin 1 in, and 1 bottom embedding degree of depth of planting basin on the upper strata moreover matches with the inside retaining degree of depth of planting basin 1 on the upper strata to make in the whole three-dimensional planting device every layer plant the water planting district that corresponds in the basin 1 have better shading and heat-insulating effect, provide good growing environment for plant roots.

The control system mainly comprises a signal acquisition module and a control module.

The signal acquisition module includes a water level sensor 34 and a PH detection sensor (not shown) to acquire information such as the water level of the nutrient solution in the water tank 31 and the PH value of the nutrient solution.

The control module comprises an electric water control valve (not shown), a controller (not shown) and the like. The electric control water valve is communicated with an external nutrient solution source, and when the acquisition module monitors that the water level of the nutrient solution in the water tank 31 is lower than a set low value, the controller controls the electric control water valve to be opened and water is filled into the water tank 31; when the water level reaches a set high value, the controller controls to close the electric control water valve and stop water injection. When the PH value in the nutrient solution is detected to exceed the set interval, the controller can send alarm information to the user through the short message or the APP to remind the user to replace the nutrient solution. The controller can also set parameters such as the starting time, the working duration and the interval of the gap working time of the water pump 33, when the working duration is long, the controller controls the water pump 33 to be started so as to supply nutrient solution into the planting pot 1, and when the working duration is long, the controller controls the water pump 33 to be stopped.

The tidal hydroponic planting pot 1 of the present embodiment is provided with a low water level drain hole 113 and a high water level drain hole 114 at the bottom thereof, and the total drain flow rate of all the drain holes is larger than the supply flow rate of the supply pipe 32 in sum. The controller is adopted to control the intermittent nutrient solution supply mode of the water pump 33 to work to form a tidal effect by the caliber and the height difference of the high-low water level drain holes 113 and the design between the total drain flow and the supply flow.

The working principle of the embodiment is as follows:

the water pump 33 is started under the control of the controller, the water pump 33 lifts nutrient solution from the water tank 31 to the highest-layer tide water planting basin 1 of the stereoscopic planting device, the liquid level of the nutrient solution in the highest-layer planting basin 1 rises continuously and finally reaches a high water level, the inflow and outflow of the nutrient solution in the basin reach balance at the moment, the nutrient solution in the highest-layer tide water planting basin 1 flows into the next-layer tide water planting basin 1 through the low water level drain hole 113 and the high water level drain hole 114 until the liquid level of the nutrient solution in the next-layer tide water planting basin 1 rises to the high water level, then flows into the next-layer tide water planting basin 1 downwards, and the rest is done in the same way to finally reach the bottommost layer of the stereoscopic planting device and then flows back to the water tank 31.

When the controller controls the water pump 33 to be shut down, the nutrient solution pages in each layer of the planting pot 1 in the three-dimensional planting device gradually recover to a low water level from top to bottom, and the root systems of the plants in the planting pots 1 are simultaneously contacted with water and air, so that the supply of oxygen, moisture and nutrients to the plants in the whole planting system is ensured.

In the embodiment, the tide-type cultivation is implemented through the three-dimensional planting device, and the specific planting method is divided into three stages: the nutrient solution supply stage of rising tide, the stage of falling tide and the stage of standing water culture.

The first stage, nutrient solution supply stage. The controller controls the water pump 33 to supply nutrient solution to the planting pot 1, the planting pot 1 comprises two drain holes with different heights, the low-water-level drain hole 113 is positioned on the plane (low-water-level surface) which is lower than the accommodating groove 121 and has the water discharge amount smaller than the supply amount of the water pump 33, and the high-water-level drain hole 114 is positioned on the plane (high-water-level surface) which is higher than the accommodating groove 121 and has the water discharge amount larger than the supply amount of the water pump 33.

And in the stage that the water pump 33 is controlled by the controller to supply nutrient solution, the input flow rate of the nutrient solution in the planting pot 1 is greater than the discharge flow rate of the nutrient solution, the nutrient solution level in the planting pot 1 reaches a high water level, and plants substrates, seeds or plant front end root systems in the containing groove 121 are submerged to convey nutrients and moisture for the plants, and the moisture and the nutrients can be stored in the substrates. When the nutrient solution reaches the high water level, the nutrient solution is discharged from the high water level discharge hole 114, and the inflow rate and the outflow rate of the nutrient solution in the planting pot 1 are balanced, so that the nutrient solution does not rise any more.

The second stage, the ebb stage. The controller controls the water pump 33 to stop supplying nutrient solution to the planting pot 1, the low-water-level drain hole 113 in the planting pot 1 continuously drains the nutrient solution, the liquid level continuously drops to the low-water-level surface in the planting pot 1, and the planting matrix in the storage tank 121 is separated from the nutrient solution in the pot body 11. The surrounding of the planting matrix and part of the root system of the plant are exposed in the air in the planting pot 1, so that abundant oxygen is provided for the plant, and the respiration of the plant is guaranteed.

And in the third stage, standing for water culture. The stage controller controls the water pump 33 to be in a closed state, the nutrient liquid level in the planting pot 1 is lower than the planting matrix in the accommodating groove 121, nutrient liquid with a certain depth is reserved in the planting cup 12, and the plant root system part is immersed in the nutrient liquid, so that the supply of water and nutrients of the plant is ensured.

The stereoscopic planting device of the embodiment has the following advantages:

(1) the building block mode is adopted, so that the modular production, packaging, transportation and assembly are facilitated, and the building block is suitable for different spaces; is particularly suitable for planting vegetables and flowers on urban roofs, balconies, indoors and offices.

(2) In the stereoscopic planting system that whole planting case was built, adopt water pump 33 to promote the nutrient solution to the highest level of stereoscopic planting system and plant the case, follow-up under the action of gravity, nutrient solution successive layer downward flow carries moisture, nutrient to each layer planting case to drive the air flow, carry oxygen for plant roots. High efficiency, energy saving and water saving.

(3) The device has single planting cup and multiple planting cup planting box, adopts cordwood system stack combination, can be according to user's needs and hobby independent assortment, has better edutainment, is particularly suitable for city primary and secondary school's farming science popularization.

(4) This planting device has intelligence and replenishes moisture, and the survival rate that the family was planted is improved to the automatic watering function.

(5) The planting device is suitable for planting various plants, and a plurality of planting pots are stacked and built, namely, a modular mode is adopted for building, and the assembly is flexible.

The above is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and various modifications and changes will occur to those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (9)

1. Tidal hydroponic planting pot, its characterized in that includes:

the flowerpot comprises a flowerpot body, a water outlet hole is formed in the flowerpot body, a first conical groove and a second conical groove are formed in the side wall of the flowerpot body, the first conical groove and the second conical groove are alternately distributed along the circumferential direction of the flowerpot body, and the taper of the first conical groove is larger than that of the second conical groove;

a planting cup which is fixed on the outer wall of the pot body and is communicated with the pot body.

2. The tidal hydroponic growth pot of claim 1,

the bottom of the planting cup is provided with a containing groove which is positioned below the communicating part of the planting cup and the pot body.

3. The tidal hydroponic growth pot of claim 1,

the lateral wall of the pot body inclines outwards from bottom to top.

4. The tidal hydroponic growth pot of claim 1,

the drain hole comprises a low water level drain hole and a high water level drain hole, and the diameter of the low water level drain hole is smaller than that of the high water level drain hole.

5. The tidal hydroponic growth pot of claim 4,

the flowerpot is characterized in that a first-stage round platform and a second-stage round platform are arranged at the bottom of the pot body, the first-stage round platform is located at the bottom of the second-stage round platform, the low-water-level drain hole is formed in the first-stage round platform, and the high-water-level drain hole is located in the second-stage round platform.

6. The stereoscopic planting device is characterized by comprising a planting device,

a base;

a plurality of tidal hydroponic planting pots as claimed in any one of claims 1 to 5, wherein a plurality of the tidal hydroponic planting pots are stacked from bottom to top, the tidal hydroponic planting pot located at the bottommost layer is arranged on the base, and in two adjacent tidal hydroponic planting pots, the bottom of the first conical groove of the upper tidal hydroponic planting pot is embedded into the top of the second conical groove of the lower tidal hydroponic planting pot; and

and the nutrient solution circulating device is used for supplying nutrient solution to the tidal hydroponic planting pot.

7. The stereoscopic planting apparatus of claim 6,

the nutrient solution circulating device comprises a water tank, a liquid supply pipe and a water pump,

the water inlet end of the water pump is communicated with the water tank, the water outlet end of the water pump is communicated with the liquid supply pipe, and liquid of the liquid supply pipe is supplied to the tide water planting basin on the highest layer.

8. The stereoscopic planting apparatus of claim 7,

and the tide water planting pots are sleeved on the liquid supply pipe.

9. The stereoscopic planting apparatus of claim 7 or 8,

the water tank is arranged in the base, the liquid supply pipe is communicated with the water tank and is positioned at the bottommost layer the tide water planting basin is communicated with the water tank.

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