CN211671527U - Plant planter - Google Patents

Abstract

The utility model belongs to the technical field of the farming technique and specifically relates to a plant planter. The planting device comprises a bevel edge planting frame, a plurality of water collecting planting grooves erected on the planting frame along the bevel edge, capillary planting cups suspended in the water collecting planting grooves, a self-flowing connecting pipe for connecting the water collecting planting grooves step by step to form a waterway channel, a water injection main pipe and a water outlet main pipe, wherein the water injection main pipe and the water outlet main pipe are arranged on the bevel edge planting frame. The utility model can arrange the cultivated plants in staggered layers step by step, thereby ensuring that the cultivated plants can not be shielded from each other, and being beneficial to the full utilization of sunlight and the free growth of the cultivated plants; meanwhile, the water in the water collecting planting groove is automatically drawn from the lower part of the soil by utilizing the capillary phenomenon generated by the capillary planting cup so as to form a water supply mode of automatically irrigating or infiltrating the roots of the plants, so that the problems of hardening of the soil and blocking of the growth of the roots of the plants, which are easily caused by direct irrigation on the soil, can be avoided, artificial irrigation is not needed, and water resources are saved.

Description

Plant planter

Technical Field

The utility model belongs to the technical field of the farming technique and specifically relates to a plant planter.

Background

Along with the development of society and the progress of science and technology, the urbanization process is accelerated continuously, and modern people in nature and farmland environment are more and more far away. In order to improve living environment and feel the smell of nature, people often use some plant racks or planting frames to arrange some growing plants or try to plant some organic vegetables and flowers in self-service balconies, living rooms, office areas and public places.

The existing plant planting frame mostly adopts a single-layer or multi-layer upright frame body structure as a main structure, so that the following defects generally exist in the process of planting and cultivating plants: 1. the space of the frame body cannot be fully utilized to increase the planting quantity of plants to the maximum extent, and the supports of the plants (particularly the plants on different layers) are easy to shield each other, so that the utilization rate (or lighting rate) of sunlight is influenced, and the growth degree of the plants is not uniform. 2. The plants need to be irrigated one by adopting an irrigation mode from the upper part of the soil, so that differentiated irrigation can not be carried out according to different plant characteristics, and water resource waste is easily caused; in addition, once the irrigation is improper, the soil is easily hardened, and the growth of the roots of the plants is seriously influenced. Space and solar energy are often fully utilized, and the space utilization rate is improved. 3. Due to the defects of structural design, intelligent or automatic control of plant irrigation cannot be realized, and the specific application range of similar devices is limited.

SUMMERY OF THE UTILITY MODEL

To the not enough of above-mentioned prior art existence, the utility model aims to provide a plant planter.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a plant planter comprising:

the bevel edge planting frame is a frame structure with a longitudinal section shaped like a right trapezoid;

the water collecting planting grooves are erected in the bevel edge planting frame along a direction perpendicular to the waist edge of the bevel edge planting frame, and are distributed in a staggered manner from top to bottom along the extending direction of the waist edge of the bevel edge planting frame;

the water collecting planting grooves are communicated with the self-flowing connecting pipes step by step and then form S-shaped waterway channels together with the water collecting planting grooves;

at least one capillary planting cup is suspended in each water collecting planting groove;

the water outlet end of the water injection main pipe is communicated with the upper port of the waterway channel through one end of the water collecting planting groove positioned at the uppermost part of the bevel edge planting frame;

and

and the water inlet end of the water outlet main pipe is communicated with the lower port of the waterway channel through one end of the water collecting and planting groove positioned at the lowest part of the bevel edge planting frame.

Preferably, the capillary planting cup comprises a cup body suspended in the water collecting planting groove, plant cultivation media filled in the cup body, water suction holes formed in the bottom surface of the cup body, and water suction cotton which penetrates through the water suction holes and is distributed, and the top end of the water suction cotton is embedded in the plant cultivation media.

Preferably, a plurality of capillary holes are uniformly distributed on the bottom surface of the cup body and around the water suction hole.

Preferably, the water collecting planting groove comprises a planting groove which is integrally in a strip groove body structure and water collecting pipes which are arranged on the side walls of the two ends of the planting groove and are distributed adjacent to the groove surface of the planting groove, and a water containing flow channel is formed between the groove surface of the planting groove and the cup bottom of the capillary planting cup; the water collecting pipe on one end side of the water collecting planting groove positioned at the uppermost part of the inclined edge planting frame is communicated with the water injection main pipe, the water collecting pipe on the other end side of the water collecting planting groove positioned at the lowermost part of the inclined edge planting frame is communicated with the water collecting pipe on one end side of the adjacent water collecting planting groove through the self-flowing connecting pipe, the water collecting pipe on one end side of the water collecting planting groove positioned at the lowermost part of the inclined edge planting frame is communicated with the water outlet main pipe, and the water collecting pipe on the other end side of the water collecting planting groove positioned at the lowermost part of the inclined edge planting frame is communicated with the water.

Preferably, the bevel edge planting rack comprises a longitudinal water pipe, a longitudinal support rod, a first left-right support rod, a second left-right support rod, a first front-back support rod, a first left-right support rod, a second left-right support rod, a first front-back support rod, a first left-back support rod, a first front-back support rod, a first left-back support rod, a second left-back support rod, a third left-right support rod, a third left-back support rod, a third left-right support rod, a third left-back support rod and a third left-right support rod are distributed in parallel, a left-right direction and a longitudinal direction water pipe is distributed in parallel, the first, A second front and back water pipe which is distributed side by side from top to bottom with the first front and back support rod and one end of which is connected with a first three-way connecting pipe on the longitudinal water pipe, a second front and back support rod which is distributed side by side from left to right with the second front and back water pipe and one end of which is connected with a first three-way connecting pipe on the longitudinal support rod, a first bevel edge support rod the top end of which is connected with the second front and back water pipe through a third three-way connecting pipe and the bottom end of which is connected with a second three-way connecting pipe on the third left and right support rod, and a second bevel edge support rod the top end of which is connected with the second front and back support rod through a V-shaped three-way pipe and the bottom end of;

a plurality of third front and rear support rods which are vertically distributed side by side with the first front and rear support rods or the first front and rear water pipes are also arranged between the first bevel edge support rod and the longitudinal water pipe and between the second bevel edge support rod and the longitudinal support rod, a plurality of support frame rods for supporting the water-collecting planting grooves are arranged between two third front and rear support rods in the same left and right plane, one end of each third front and rear support rod is connected with the corresponding longitudinal water pipe or longitudinal support rod through a fourth three-way connecting pipe, and the other end of each third front and rear support rod is connected with the corresponding first bevel edge support rod or second bevel edge support rod through a fifth three-way connecting pipe;

the water injection main pipe is communicated with one end of the water collecting planting groove at the top of the planting frame through the longitudinal water pipe and the second front and back water pipes, and the water outlet main pipe is communicated with one end of the water collecting planting groove at the bottom of the planting frame through the first front and back water pipes and the inclined edge.

Preferably, the included angle between the waist edge and the bottom edge of the bevel edge planting frame is 60-65 degrees.

Preferably, the water injection main pipe is provided with an electromagnetic switch valve, the water collecting planting grooves at the top and the bottom of the inclined edge planting frame are provided with liquid level sensors, and the electromagnetic switch valve performs opening or closing actions according to output signals of the liquid level sensors.

Due to the adoption of the scheme, the utility model can arrange the cultivated plants in staggered layers step by step, thereby ensuring that the cultivated plants are not shielded mutually, and being beneficial to the full utilization of sunlight and the free growth of the cultivated plants; meanwhile, the water in the water collecting planting groove is automatically drawn from the lower part of the soil by utilizing the capillary phenomenon generated by the capillary planting cup so as to form a water supply mode of automatically irrigating or infiltrating the roots of the plants, so that the problems that the soil is easily hardened and the roots of the plants are prevented from growing because of direct irrigation on the soil can be avoided, the artificial irrigation is not needed, and the water resource is saved; in addition, by the waterway system distributed on the whole planting machine, not only can the water flow be ensured to flow automatically from top to bottom, but also the waterway system for heat exchange can be formed on the whole planting machine, thereby creating conditions for reducing the environmental temperature of plant planting and cultivation.

Drawings

Fig. 1 is an assembly diagram of the overall structure of an embodiment of the present invention;

fig. 2 is a schematic cross-sectional structure view of the capillary planting cup of the embodiment of the invention under assembly;

fig. 3 is a schematic view of the flow direction of the water path according to the embodiment of the present invention.

Detailed Description

The embodiments of the invention will be described in detail below with reference to the drawings, but the invention can be implemented in many different ways as defined and covered by the claims.

As shown in fig. 1 to 3, the present embodiment provides a plant planter, which includes:

the bevel edge planting frame has a frame body structure with a longitudinal section similar to a right trapezoid, wherein the right trapezoid can be understood as a standard right trapezoid geometric shape and can also refer to other similar or similar geometric shapes with an inclined surface;

the water collecting planting grooves 200 are erected in the bevel edge planting frame along the direction perpendicular to the waist edge of the bevel edge planting frame, and the water collecting planting grooves 200 are distributed in a staggered manner from top to bottom along the extending direction of the waist edge of the bevel edge planting frame (namely, the water collecting planting grooves 200 form a morphological structure similar to a step along the waist edge direction of the bevel edge planting frame);

the plurality of self-flowing connecting pipes 300 are used for connecting the water collecting planting grooves 200 in series step by step and then forming a water channel in an S shape together with the water collecting planting grooves (namely, the water channel is equivalent to a water channel in an S shape formed by connecting the plurality of water collecting planting grooves 200 in series continuously by using the plurality of self-flowing connecting pipes 300);

a plurality of capillary planting cups (400), at least one capillary planting cup (400) is suspended in each water collecting planting groove (200);

the water outlet end of the water injection main pipe 500 is communicated with the upper port of the waterway channel through one end of the water collecting planting groove 200 positioned at the uppermost part of the inclined planting frame; the water injection main pipe 500 can be connected with a water pumping device (such as a water pump) for supplying water into the water collecting and planting tank 200;

and

the water inlet end of the water outlet main pipe 600 is communicated with the lower port of the waterway channel through one end of the water collecting and planting groove 200 positioned at the lowest part of the bevel edge planting frame.

Therefore, by utilizing the structural form that the whole bevel edge planting frame is similar to a right trapezoid and the mode that the plurality of water collecting planting grooves 200 are distributed on the bevel edge planting frame in a step-by-step staggered manner, structural conditions can be created for the step-by-step staggered arrangement of the cultivated plants planted in the capillary planting cup 400, so that the cultivated plants are not shielded from each other, and the full utilization of sunlight and the free growth of cultivated plant individuals are facilitated; meanwhile, the water in the water collecting planting groove 200 is automatically drawn from the lower part of the soil (namely the bottom of the capillary planting cup 400) by using the water collecting planting groove 200 as a carrier for water collection and combining with the capillary phenomenon generated by the capillary planting cup 400, so that a water supply mode for automatically irrigating or infiltrating the roots of the plants is formed, the problems that the soil is hardened and the roots of the plants are hindered from growing easily caused by directly irrigating the soil can be effectively avoided, and the artificial irrigation is not needed, so that the water resource is saved; in addition, by utilizing the communication relationship among the water injection main pipe 500, the water outlet main pipe 600 and the waterway channels, the bevel edge planting frame, the water collecting planting groove 200, the capillary planting cup 400 and the like can be integrated into a whole, so that a waterway system which is distributed on the whole planter is formed, the water flow can be ensured to flow automatically from top to bottom, a waterway system with cold and heat exchange can be formed on the whole planter, and conditions are created for reducing the environmental temperature of plant planting and cultivation.

In order to enhance the capillary action of the capillary planting cup 400 and achieve automatic water absorption in the water collecting planting groove 200, the capillary planting cup 400 of the present embodiment includes a cup body 401 suspended in the water collecting planting groove 200, a plant cultivation medium 402 (which may be pure soil or soil containing nutrients or fertilizers required for plant growth according to actual conditions) filled in the cup body 401, water absorption holes opened on the bottom surface of the cup body 401, and water absorption cotton 403 penetrating through the water absorption holes and distributed and embedded at the top end in the plant cultivation medium 402. Thus, the water absorbent cotton 403 having different water absorption rates can be installed in the water absorption holes according to different plant characteristics, and the water in the water collecting planting grooves 200 is transferred into the plant growing medium 402 by the adsorption of the water absorbent cotton 403 to the water, thereby maintaining the plant growing medium 402 in a wet state so that the plant can absorb the water as required.

In view of the fact that plants have developed root systems and can create a better space environment for the growth of the plants, a plurality of capillary holes (not shown in the figure) are uniformly distributed on the bottom surface of the cup body 401 and around the water suction holes. Therefore, when the plant is produced to a certain extent, the root system of the plant can extend to the bottom of the capillary planting cup 400 through the plant cultivation medium 402 and finally enter the water collecting and planting tank 200 through the capillary hole, so that the root system of the plant can directly draw water. Therefore, the water intake amount can be completely determined by the plant, and the problems of root rot or water resource waste are avoided to a certain extent.

In order to optimize the structure of the water-collecting planting groove 200 and create structural conditions for the collection of water, the water-collecting planting groove 200 of the embodiment comprises a planting groove 201 which is integrally in a strip groove body structure and water collecting pipes 202 which are arranged on the side walls of two ends of the planting groove 201 and are distributed near the groove surface of the planting groove 201, and a water containing flow passage b is formed between the groove surface of the planting groove 201 and the cup bottom of the capillary planting cup 400; the water collecting pipe 202 on one end side of the water collecting and planting groove 200 positioned at the uppermost part of the inclined planting frame is communicated with the water injection main pipe 500, the water collecting pipe 202 on the other end side is communicated with the water collecting pipe 202 on one end side of the adjacent water collecting and planting groove 200 through the self-flow connecting pipe 300, the water collecting pipe 202 on one end side of the water collecting and planting groove 200 positioned at the lowermost part of the inclined planting frame is communicated with the water outlet main pipe 600, and the water collecting pipe 202 on the other end side is communicated with the water collecting pipe 202 on one end side of the adjacent water collecting and planting groove 200 through the self-flow connecting pipe 300. Therefore, the formed water containing flow channel b can ensure that a certain amount of water can be stored in each layer of the water collecting planting groove 200, and when the water supply is stopped or is insufficient, the water supply effect on the plants can still be ensured by utilizing the volatilization of the water and the adsorption of the water absorbing cotton 403 on the water (namely, the capillary phenomenon of the capillary planting cup 400). When the water is pumped into the water collecting and planting grooves 200 through the water injection main pipe 500 by using the water pumping device, when the liquid level in each water collecting and planting groove 200 is higher than the water containing channel b, the liquid can sequentially flow into the water collecting and planting groove 200 of the next stage through the corresponding self-flow connecting pipe 300, so that a water self-flow channel is formed.

The structure of the whole planter is optimized to the maximum extent, and a waterway supply system can be perfectly formed by each component part; the bevel edge planting rack of the embodiment comprises a longitudinal water pipe 101, a longitudinal support rod 102, a first left-right support rod 104, a second left-right support rod 106, a first front-back support rod 107 and a second front-back support rod 106, wherein the longitudinal water pipe 101 is distributed in parallel from left to right, the first left-right support rod 102 is arranged between the top of the longitudinal water pipe 101 and the top of the longitudinal support rod 102 and is connected with the longitudinal water pipe 101 and the longitudinal support rod 102 into a whole through two first three-way connecting pipes 103, the second left-right support rod 106 is arranged in parallel from left to right, one end of the first front-back support rod 107 is connected with the four-way connecting pipe 105 on the longitudinal support rod 102, and one end of the first front-back support rod 108 is connected with the four-way connecting pipe 105 on the longitudinal water pipe 101, the first front-back support rod 107 and the first front-back support A third left and right support rod 110 connected with the water pipe 108 into a whole, a second front and back water pipe 111 arranged side by side up and down with the first front and back support rod 107 and having one end connected with the first three-way connection pipe 103 on the longitudinal water pipe 101, a second front and back support rod 112 arranged side by side with the second front and back water pipe 111 and having one end connected with the first three-way connection pipe 103 on the longitudinal support rod 102, a first bevel edge support rod 114 having a top end connected with the second front and back water pipe 111 through a third three-way connection pipe 113 and a bottom end connected with the second three-way connection pipe 109 on the third left and right support rod 110, and a second bevel edge support rod 116 having a top end connected with the second front and back support rod 112 through a V-shaped three-way pipe 115 and a bottom end connected with the second three-way connection pipe 109 on the third left and right support; a plurality of third front and rear support rods 117 which are distributed side by side up and down with the first front and rear support rods 107 or the first front and rear water pipes 108 are also arranged between the first bevel support rod 114 and the longitudinal water pipe 101 and between the second bevel support rod 116 and the longitudinal support rod 102, a plurality of support rod bars 118 for supporting the water collecting and planting grooves 200 are arranged between two third front and rear support rods 117 which are positioned in the same left and right plane, one end of each third front and rear support rod 117 is connected with the corresponding longitudinal water pipe 101 or the longitudinal support rod 102 through a fourth three-way connecting pipe 119, and the other end is connected with the corresponding first bevel support rod 114 or the second bevel support rod 116 through a fifth three-way connecting pipe 120; the water injection header pipe 500 is communicated with one end of the water collecting and planting groove 200 at the top of the inclined edge planting frame through the longitudinal water pipe 101 and the second front-back water pipe 111, and the water outlet header pipe 600 is communicated with one end of the water collecting and planting groove 200 at the bottom of the inclined edge planting frame through the first front-back water pipe 108.

Therefore, the longitudinal water pipe 104, the first front-back water pipe 108, the second front-back water pipe 111, the corresponding four-way connecting pipe 105, the first three-way connecting pipe 103, the third three-way connecting pipe 113 and the like can be used as supporting parts for forming the whole bevel edge planting frame, and a complete one-way water flow circulation channel can be formed by mutual communication of the longitudinal water pipe, the first front-back water pipe 108, the second front-back water pipe 111, the corresponding four-way connecting pipe 105, the first three-way connecting pipe 103, the third three-way connecting pipe 113 and the like, so that the water flow can be distributed on the whole bevel edge planting frame in the flowing process, and the ambient temperature of plant planting can be properly reduced by; meanwhile, the third front and rear support rods 117 can be used for reinforcing the structure of the bevel edge planting frame, and the number and the distance of the third front and rear support rods can be selected to provide conditions for specific placement positions and numbers of the water collecting and planting grooves 200. In addition, when the concrete implementation is carried out, the corresponding support rods can be used for simultaneously carrying out corresponding plugging on the corresponding ports of the three-way connecting pipe, the four-way connecting pipe and the like so as to ensure the through of the water pipe.

As a preferred scheme, in order to meet the requirements of plant growth and illumination, the included angle (namely, the inclination angle) between the waist edge and the bottom edge of the bevel edge planting frame is 60-65 degrees; among them, 63 ° is preferable.

In addition, in order to realize the automatic or intelligent water supply control of the whole planter, an electromagnetic switch valve 700 may be installed on the water injection main pipe 500 (of course, the specific position thereof may also be selectively installed on the longitudinal water pipe 101 or the second front-back water pipe 111), liquid level sensors 800 (such as non-contact liquid level switches) are installed in the water collection planting troughs 200 located at the uppermost and lowermost of the inclined planting racks, and the electromagnetic switch valve 700 performs an opening or closing operation according to an output signal of the liquid level sensor 800. Therefore, the liquid level sensor 800 is used for detecting the water level conditions in the water collecting and planting groove 200 at the highest point and the lowest point of the whole planter, and when the water level reaches the lower limit, the electromagnetic switch valve 700 can be controlled to be opened to supplement water through the water injection main pipe 500; when the water level reaches the high limit, the water supply pipeline of the water injection main pipe 500 is closed; therefore, the automatic or intelligent water supply control of the planter can be realized by utilizing the matching of the liquid level sensor 800 and the electromagnetic switch valve 700 and the regulation and control of the liquid level sensor 800 and the electromagnetic switch valve 700, and the defects caused by manual irrigation are overcome.

The above only is the preferred embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structures or equivalent flow changes made by the contents of the specification and the drawings, or directly or indirectly applied to other related technical fields, are included in the same way in the protection scope of the present invention.

Claims (7)

1. A plant planter which is characterized in that: it comprises

The bevel edge planting frame is a frame structure with a longitudinal section shaped like a right trapezoid;

the water collecting planting grooves (200) are erected in the bevel edge planting frame along the direction perpendicular to the waist edge of the bevel edge planting frame, and the water collecting planting grooves (200) are distributed in a staggered manner from top to bottom in a staggered manner along the extending direction of the waist edge of the bevel edge planting frame;

the self-flowing connecting pipes (300) are used for connecting the water collecting planting grooves (200) in series step by step and then form S-shaped waterway channels together with the water collecting planting grooves;

capillary planting cups (400), at least one capillary planting cup (400) is suspended in each water collecting planting groove (200);

the water outlet end of the water injection main pipe (500) is communicated with the upper port of the waterway channel through one end of the water collecting and planting groove (200) positioned at the uppermost part of the inclined edge planting frame;

and

and the water inlet end of the water outlet header pipe (600) is communicated with the lower port of the waterway channel through one end of the water collecting and planting groove (200) positioned at the lowest part of the bevel edge planting frame.

2. The plant planter according to claim 1, wherein: the capillary planting cup (400) comprises a cup body (401) suspended in the water collecting planting groove (200), plant cultivation media (402) filled in the cup body (401), water suction holes formed in the bottom surface of the cup body (401), and water suction cotton (403) which penetrates through the water suction holes and is distributed, and the top end of the water suction cotton is embedded in the plant cultivation media (402).

3. The plant planter according to claim 2, wherein: a plurality of capillary holes are uniformly distributed on the bottom surface of the cup body (401) and around the water suction hole.

4. The plant planter according to claim 1, wherein: the water collecting planting groove (200) comprises a planting groove (201) which is integrally in a strip groove body structure and water collecting pipes (202) which are arranged on the side walls of the two ends of the planting groove (201) and are distributed adjacent to the groove surface of the planting groove (201), and a water containing flow channel (b) is formed between the groove surface of the planting groove (201) and the cup bottom of the capillary planting cup (400); the water collecting pipe (202) on one end side of the water collecting and planting groove (200) positioned at the uppermost part of the inclined edge planting frame is communicated with the water injection main pipe (500), the water collecting pipe (202) on the other end side is communicated with the water collecting pipe (202) on one end side of the adjacent water collecting and planting groove (200) through the self-flowing connecting pipe (300), the water collecting pipe (202) on one end side of the water collecting and planting groove (200) positioned at the lowermost part of the inclined edge planting frame is communicated with the water outlet main pipe (600), and the water collecting pipe (202) on the other end side is communicated with the water collecting pipe (202) on one end side of the adjacent water collecting and planting groove (200) through the self-flowing connecting pipe (300).

5. The plant planter according to claim 1, wherein: the bevel edge planting frame comprises a longitudinal water pipe (101), a longitudinal support rod (102) with the longitudinal water pipe (101) distributed side by side left and right, a first left-right support rod (104) arranged between the top of the longitudinal water pipe (101) and the top of the longitudinal support rod (102) and connecting the longitudinal water pipe (101) and the longitudinal support rod (102) into a whole through two first three-way connecting pipes (103), a second left-right support rod (106) arranged between the bottom of the longitudinal water pipe (101) and the bottom of the longitudinal support rod (102) and connecting the longitudinal water pipe (101) and the longitudinal support rod (102) into a whole through two four-way connecting pipes (105), a first front-back support rod (107) with one end connected with the four-way connecting pipe (105) on the longitudinal water pipe (101), a first front-back water pipe (108) with one end connected with the four-way connecting pipe (105) on the longitudinal support rod (102) and a first front-back water pipe (108) distributed side by side left and right with the first front-back, A third left and right support rod (110) which is distributed with the second left and right support rod (106) in a front and back side by side way and is connected with the first front and back support rod (107) and the first front and back water pipe (108) into a whole through two second three-way connecting pipes (109), a second front and back water pipe (111) which is distributed with the first front and back support rod (107) in a top and down side by side way and has one end connected with the first three-way connecting pipe (103) on the longitudinal water pipe (101), a second front and back support rod (112) which is distributed with the second front and back water pipe (111) in a left and right side by side way and has one end connected with the first three-way connecting pipe (103) on the longitudinal support rod (102), a first bevel edge (114) which has the top end connected with the second front and back water pipe (111) through a third three-way connecting pipe (113) and has the bottom end connected with the second three-way connecting pipe (109) on the third left and right support rod (110), and left support rod (112), and right support rod (106 And the bottom end of the second bevel edge supporting rod (116) is connected with a second three-way connecting pipe (109) on the third left-right supporting rod (110);

a plurality of third front and rear support rods (117) which are vertically distributed side by side with the first front and rear support rods (107) or the first front and rear support rods (108) are further arranged between the first bevel support rod (114) and the longitudinal water pipe (101) and between the second bevel support rod (116) and the longitudinal support rod (102), a plurality of support frame rods (118) for supporting the water collecting and planting grooves (200) are arranged between two third front and rear support rods (117) which are positioned in the same left-right plane, one end of each third front and rear support rod (117) is connected with the corresponding longitudinal water pipe (101) or the longitudinal support rod (102) through a fourth three-way connecting pipe (119), and the other end of each third front and rear support rod is connected with the corresponding first bevel support rod (114) or the second bevel support rod (116) through a fifth three-way connecting pipe (120);

the one end that the frame was planted to the catchment of the top was planted to water injection house steward (500) through vertical water pipe (101) and second front and back to water pipe (111) and hypotenuse is linked together, water outlet house steward (600) are planted one end of planting groove (200) with the hypotenuse that catchments of frame below is planted through first front and back to water pipe (108) and hypotenuse and are linked together.

6. The plant planter according to claim 1, wherein: the included angle between the waist edge and the bottom edge of the bevel edge planting frame is 60-65 degrees.

7. A plant planter according to any one of claims 1 to 6, wherein: the water injection main pipe (500) facial make-up is equipped with electromagnetic switch valve (700), is located all installed level sensor (800) in the frame is planted to the hypotenuse collection water planting groove (200) the top and the below, electromagnetic switch valve (700) open or close the action according to level sensor (800)'s output signal execution.

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