CN108207406B - Splice module and planting container - Google Patents

Abstract

The invention relates to the technical field of greening and environmental protection, and provides a splicing module and a planting container, wherein the splicing module comprises a first cavity and a second cavity for planting plants, a first splicing part, a second splicing part, a third splicing part and a fourth splicing part are arranged on the splicing module, and the first splicing part, the second splicing part, the third splicing part and the fourth splicing part are positioned at the periphery of the splicing module and are respectively used for splicing another splicing module adjacent to the splicing module in the corresponding direction, so that the splicing modules capable of being mutually spliced are formed; the planting container comprises a plurality of the splicing modules, can be spliced freely according to specific needs, has higher flexibility, can be changed freely according to specific needs, has good landscape and ecological benefits, and is suitable for various places such as indoor or outdoor places.

Description

Splice module and planting container

Technical Field

The invention relates to the technical field of greening and environmental protection, in particular to a splicing module and a planting container.

Background

With the continuous development of science and economy, cities are rapidly expanded, land resources are gradually deficient, so that the traditional greening form is not suitable for urban greening construction, thus planting containers such as plant curtain walls, vertical greening systems, movable scenic walls and the like are produced, novel greening forms are formed, the planting containers are combined with the characteristics of urban construction and the current situation of undersize soil, the novel greening structure changes the traditional greening mode, can realize the greening effect, can be mutually blended with urban buildings, can be applied to indoor places such as families, offices, exhibitions and the like, can also be applied to outdoor environments such as building outer walls, guardrails, parks and the like, has good landscapes and ecological benefits, and has the most critical advantages of small occupied area and good greening effect. However, the existing planting container is fixed in structure, the environment is usually required to be known in advance, then corresponding setting is carried out according to the environmental conditions, the flexibility of free change is not provided, and when the environment changes, the planting container is required to be moved or removed integrally, so that the resource waste is caused. Therefore, there is a need to provide a new solution to the problems existing in the prior art.

Disclosure of Invention

The invention aims to solve the technical problem of providing a splicing module capable of being spliced with each other and a planting container comprising the splicing module and capable of being freely changed.

The technical scheme adopted by the invention for solving the technical problems is as follows:

the utility model provides a splice module, including first chamber and the second chamber that is used for planting the plant, be provided with first splice, second splice, third splice and fourth splice on the splice module, first splice the second splice third splice with fourth splice is located splice around the splice module to be used for splice with splice module corresponding another splice module adjacent in direction respectively.

As an improvement of the above technical solution, the device further comprises a back plate, an intermediate plate, a pair of symmetrical first side walls and a pair of symmetrical second side walls, wherein the first side walls and the second side walls are perpendicular to the back plate, the intermediate plate is arranged between the first side walls and the second side walls and perpendicular to the back plate, the intermediate plate, the back plate and the first side walls jointly enclose a first cavity, and the intermediate plate, the back plate and the second side walls jointly enclose a second cavity.

As a further improvement of the technical scheme, the first splicing part is arranged on the upper portion of the first side wall, the second splicing part is arranged on the lower portion of the second side wall, and the third splicing part and the fourth splicing part are respectively arranged on two sides of the backboard.

As a further improvement of the above technical solution, the first splicing part includes a pair of first splicing surfaces and a pair of mounting grooves, the second splicing part includes a pair of second splicing surfaces and a pair of mounting ribs, the mounting grooves are used for being clamped with the mounting ribs on the adjacent splicing modules, the mounting ribs are used for being clamped with the mounting grooves on the adjacent splicing modules, and a third cavity is defined by one first splicing surface, one second splicing surface, one first side wall, one second side wall and the back plate corresponding to one side of the third splicing part; and a fourth cavity is defined by the first splicing surface, the second splicing surface, the first side wall, the second side wall and the backboard corresponding to one side of the fourth splicing part.

As a further improvement of the technical scheme, the third splicing part is a clamping structure, the fourth splicing part is a clamping hole structure, the clamping structure is used for being matched and buckled with the clamping holes on the adjacent splicing modules, and the clamping hole structure is used for being matched and buckled with the clamping structure on the adjacent splicing modules.

As a further improvement of the above technical solution, a plurality of ventilation holes are provided on each of the first side wall and the second side wall.

As a further improvement of the above technical solution, the first side wall and the intermediate plate are arranged at an obtuse angle, and the second side wall and the intermediate plate are arranged at an obtuse angle.

As a further improvement of the technical scheme, the novel solar cell panel further comprises a front plate, wherein the front plate is parallel to the back plate, the first side wall, the second side wall and the middle plate are arranged between the front plate and the back plate, and notches are respectively arranged on the front plate at positions corresponding to the first cavity and the second cavity.

As a further improvement of the above technical solution, the device further comprises a guide groove for penetrating the pipeline, wherein the guide groove is arranged at the upper part of the first side wall.

The planting container comprises a plurality of the splicing modules, wherein adjacent splicing modules are mutually spliced through the first splicing part, the second splicing part, the third splicing part and the fourth splicing part.

As the improvement of the technical scheme, the planting container further comprises a binding edge arranged on the edge of the planting container, wherein the binding edge comprises a plurality of frames and a plurality of connecting bodies, and the frames and the connecting bodies are mutually spliced to form the binding edge.

As a further improvement of the technical scheme, the planting container further comprises a water tank, wherein the water tank is arranged at the lower part of the planting container and comprises a tank body and a splicing body, and the tank body and the splicing body are mutually spliced to form the water tank.

The beneficial effects of the invention are as follows:

the splicing module comprises a first cavity and a second cavity for planting plants, wherein a first splicing part, a second splicing part, a third splicing part and a fourth splicing part are arranged on the splicing module, and the first splicing part, the second splicing part, the third splicing part and the fourth splicing part are positioned at the periphery of the splicing module and are respectively used for splicing with another splicing module adjacent to the splicing module in the corresponding direction, so that mutually spliced splicing modules are formed; the planting container comprises a plurality of splicing modules, can be spliced freely according to specific needs, has higher flexibility, can be changed freely according to specific needs, and is suitable for various places.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the following description will briefly explain the drawings that are required to be used in the description of the embodiments:

FIG. 1 is a schematic diagram of a splice module according to an embodiment of the present invention;

FIG. 2 is a schematic perspective view of the embodiment of FIG. 1 at a first angle;

FIG. 3 is a schematic perspective view of the embodiment of FIG. 1 at a second angle;

FIG. 4 is a schematic perspective view of the embodiment of FIG. 1 at a third angle;

FIG. 5 is a schematic view showing the structure of a first embodiment of the planting container of the present invention;

FIG. 6 is a schematic view of a plurality of splice modules in the planting container shown in FIG. 5;

FIG. 7 is a schematic view showing the construction of a second embodiment of the planting container of the present invention;

FIG. 8 is a schematic diagram illustrating the construction of one embodiment of a binding, sink in the embodiment of FIG. 7;

fig. 9 is an exploded view of fig. 8.

Detailed Description

The conception, specific structure, and technical effects produced by the present invention will be clearly and completely described below with reference to the embodiments and the drawings to fully understand the objects, features, and effects of the present invention. It is apparent that the described embodiments are only some embodiments of the present invention, but not all embodiments, and that other embodiments obtained by those skilled in the art without inventive effort are within the scope of the present invention based on the embodiments of the present invention. In addition, all the coupling/connection relationships referred to in the patent are not direct connection of the single-finger members, but rather, it means that a better coupling structure can be formed by adding or subtracting coupling aids depending on the specific implementation. The description of the orientations of the various elements of the invention in relation to the top, bottom, left, right, etc. is merely illustrative of the relative positions of the various elements of the invention in the drawings. The technical features of the invention can be interactively combined on the premise of no contradiction and conflict.

Fig. 1 is a schematic structural view of an embodiment of a splice module according to the present invention, fig. 2 is a schematic perspective view of a first angle of the embodiment shown in fig. 1, fig. 3 is a schematic perspective view of a second angle of the embodiment shown in fig. 1, and referring to fig. 1 to 3, a splice module provided in this embodiment may be used for splicing to form a planting container, so as to plant plants. The splice module 100 includes a back panel 110, an intermediate panel 120, a pair of symmetrical first side walls 130, and a pair of symmetrical second side walls 140, the first side walls 130 and the second side walls 140 being perpendicular to the back panel 110, the intermediate panel 120 being disposed between the first side walls 130 and the second side walls 140 and perpendicular to the back panel 110, the intermediate panel 120, the back panel 110, and the first side walls 130 collectively enclosing a first cavity 1, and the intermediate panel 120, the back panel 110, and the second side walls 140 collectively enclosing a second cavity 2. The first splicing part 150, the second splicing part 160, the third splicing part 111 and the fourth splicing part 112 are arranged on the splicing module 100, and the first splicing part 150, the second splicing part 160, the third splicing part 111 and the fourth splicing part 112 are located around the splicing module.

The first splicing part 150 is disposed at the upper part of the first sidewall 130, the second splicing part 160 is disposed at the lower part of the second sidewall 140, and the third splicing part 111 and the fourth splicing part 112 are disposed at both sides of the back plate 110, respectively. Wherein the first splice 150 includes a pair of first splice faces 151 and a pair of mounting slots 152, and the second splice 160 includes a pair of second splice faces 161 and a pair of mounting ribs 162. The mounting groove 152 is used for being clamped with a mounting edge on another splicing module, the mounting edge 162 is used for being clamped with a mounting groove on another splicing module, and the backboard 110, a first splicing surface 151, a second splicing surface 161, a first side wall 130 and a second side wall 140 corresponding to one side of the third splicing part 111 jointly enclose a third cavity 3; the back plate 110, a first splicing surface 151 corresponding to one side of the fourth splicing portion 112, a second splicing surface 161, a first side wall 130, and a second side wall 140 together define the fourth cavity 4.

The splicing modules are mutually spliced with the splicing modules around the splicing modules through the first splicing part 150, the second splicing part 160, the third splicing part 111 and the fourth splicing part 112, so that the first cavity 1, the second cavity 2, the third cavity 3 and the fourth cavity 4 correspond to the second cavity, the first cavity, the fourth cavity and the third cavity of the adjacent splicing modules to form a planting cavity together for planting plants.

The third splice part 111 is a fastening structure, the fourth splice part 112 is a fastening hole structure, the fastening structure is used for being fastened with fastening holes on other splice modules in a matching way, and the fastening hole structure is used for being fastened with fastening structures on other splice modules in a matching way.

The first side wall 130 is provided with a plurality of first vent holes 131, and the first vent holes 131 respectively communicate the first cavity 1 with the third cavity 3 and the fourth cavity 4. The second side wall 140 is provided with a plurality of second vent holes 141, and the second vent holes 141 respectively communicate the second chamber 2 with the third chamber 3 and the fourth chamber 4. The first sidewall 130 and the middle plate 120 are disposed at an obtuse angle, and the second sidewall 140 and the middle plate 120 are disposed at an obtuse angle, so that the first sidewall 130, the second sidewall 140 and the middle plate 120 integrally form a structure with an approximate X-shaped cross section.

The splice module 100 further includes a front plate 170, the front plate 170 is parallel to the back plate 110, the first side wall 130, the second side wall 140 and the middle plate 120 are disposed between the front plate 170 and the back plate 110, and corresponding first notches 171, second notches 172, third notches 173 and fourth notches 174 are disposed on the front plate 170 corresponding to the first cavity 1, the second cavity 2, the third cavity 3 and the fourth cavity 4. The front plate 170 may block moisture or planting matrix within the first, second, third and fourth chambers 1, 2, 3 and 4 from escaping. The first notch 171 and the second notch 172 are formed as a half regular hexagon cut from a midpoint connecting line of opposite sides of a complete regular hexagon, so that when two adjacent splicing modules are spliced, the first notch of the lower splicing module and the second notch of the upper splicing module are combined to form a complete first planting hole of the regular hexagon for planting plants. The third notch 173 and the fourth notch 174 are also shaped as a half regular hexagon, which is formed by cutting off the connection line between two vertices of a complete regular hexagon, so that when two adjacent splicing modules are spliced, the fourth notch of the splicing module positioned on the left side and the third notch of the splicing module positioned on the right side are combined to form a complete second planting hole of the regular hexagon for planting plants. The first planting holes and the second planting holes are identical in area, so that planting holes formed after the splicing modules are spliced are consistent, and planting is convenient.

The intermediate plate 120 is provided with a support structure 121, the support structure 121 being located in the first chamber 1 for securing objects placed in the first chamber 1. The support structure 121 is specifically a tapered column extending vertically upwards from the surface of the middle plate 120, and in this embodiment, the support structure 121 includes two tapered columns, and the two tapered columns are located on one side of the first cavity 1 near the front plate 170, and the connection line of the two tapered columns is parallel to the front plate. In particular, the support structure 121 may also include a plurality of tapered posts, where the tapered posts may be arranged according to particular needs and processing conditions, e.g., the tapered posts may also be arranged from the front plate toward the back plate.

The upper portion of the splice module 100 is further provided with a guide groove 180 for penetrating the pipe, and the guide groove 180 is provided at the upper portion of the first sidewall. In this embodiment, the guide groove 180 is recessed downward from the first splicing surface, and can be used to pass through the water pipe, so as to supply water into the first cavity.

When the splicing module of the embodiment is used for splicing, the first cavity 1 is located above, the second cavity 2 is located below, an overflow port is arranged in the first cavity 1, and redundant water in the first cavity can be respectively discharged into the second cavity 2, the third cavity 3 and the fourth cavity 4 through the overflow port. Specifically, two groups of overflow ports are respectively disposed at the lower portion of the first sidewall 130 near the middle plate 120, and the first overflow port 132 is located on one side of the first sidewall corresponding to the third cavity and communicates the first cavity 1 with the third cavity 3. The second overflow port 133 is positioned on one side of the first side wall 130 corresponding to the fourth cavity 4, and the second overflow port 133 communicates the first cavity 1 with the fourth cavity 4; the lower portions of the first overflow port 132 and the second overflow port 133 are spaced from the intermediate plate 120 by a distance of 3 to 5mm, so that moisture stored in the first chamber 1 exceeding the height can be discharged into the third chamber 3 and the fourth chamber 4, respectively. In this embodiment, the first overflow port 132 and the second overflow port 133 are a pair of rectangular holes, respectively. The middle plate 120 is provided with a boss 122 protruding upwards from the surface of the middle plate 120, the boss 122 is provided with a third overflow port 123, the third overflow port 123 is a through hole penetrating through the boss 122 and the middle plate 120, and the third overflow port 123 communicates the first cavity 1 with the second cavity 2. The height of the boss 122 from the surface of the intermediate plate 120 is 3 to 5mm, so that the height of the port of the third overflow port 123 from the surface of the intermediate plate is 3 to 5mm, thereby draining the water stored in the first chamber 1 exceeding the height into the second chamber 2. Through the first overflow port, the second overflow port and the third overflow port, redundant water rows in the first cavity 1 can be respectively discharged into the second cavity 2, the third cavity 3 and the fourth cavity 4, so that excessive accumulated water is avoided.

Fig. 4 is a schematic perspective view of the third angle of the embodiment shown in fig. 1, referring to fig. 4, a rectangular groove 134 is further disposed at the first overflow port 132, and the rectangular groove 134 communicates with the rectangular hole and extends from the surface of the first sidewall 130 located in the third cavity 3 to the third cavity 3, so as to guide the water overflowed from the first cavity 1 into the third cavity 3. The second overflow port 133 is provided in the same manner as the first overflow port.

The back plate 110 is further provided with mounting holes 113 for penetrating the fixing members, so that the spliced module is fixed on a wall or other mounting surfaces, and the back plate 110 further comprises a plurality of reinforcing ribs 114 for reinforcing the strength of the back plate 110, so that the stable mounting is facilitated.

Fig. 5 is a schematic structural view of a first embodiment of a planting container according to the present invention, fig. 6 is a schematic structural view of a plurality of splicing modules in the planting container shown in fig. 5, and referring to fig. 5 and 6, the planting module according to the present embodiment includes a plurality of the above-mentioned splicing modules 100, and each splicing module 100 and other splicing modules 100 around the splicing module are mutually spliced by the above-mentioned first splicing part, second splicing part, third splicing part and fourth splicing part to form a vertical planting container, and form a plurality of planting cavities 200 for accommodating planting substrates and planting plants. Taking four splicing modules as an example, in fig. 6, the directions in the corresponding diagrams of the four splicing modules are respectively an upper splicing module 101, a lower splicing module 102 and a left splicing module 103, and the second splicing part of the upper splicing module 101 and the first splicing part of the lower splicing module 102 are mutually clamped, so that a first planting cavity 210 is formed by jointly combining the second cavity on the upper splicing module 101 and the first cavity on the lower splicing module 102, and a supporting device arranged on a middle plate in the first planting cavity can fix planting matrixes in the middle plate, thereby correspondingly fixing plants and preventing the plants from falling off. The fourth splicing part of the left splicing module 103 and the third splicing part of the upper splicing module 101 are mutually buckled, so that the fourth cavity of the left splicing module and the third cavity of the upper splicing module 101 are jointly combined to form a second planting cavity 220, a plurality of splicing modules are spliced in the mode to form a planting container in such a way, a plurality of planting cavities 200 which are vertically stacked and arranged are formed, and the first planting cavities 210 and the second planting cavities 220 are staggered.

Referring to fig. 1, 2, 5 and 6, the splice modules 100 of the planting container are communicated through the first ventilation holes 131 formed in the first side wall 130 and the second ventilation holes 141 formed in the second side wall 140, so that the whole planting container realizes internal ventilation, and plant root growth is facilitated. A water pipe (not shown) is penetrated through the guide groove 180 provided on the first splicing surface 151 of the splicing module 100, thereby supplying water into the first chamber 1. Water pipes (not shown) are arranged on the splicing modules of the planting container on the upper part in a penetrating way, water is supplied from top to bottom, and redundant water in the first cavity 1 can be respectively discharged into the second cavity 2, the third cavity 3 and the fourth cavity 4 through the first overflow port 132, the second overflow port 133 and the third overflow port 123, so that the redundant water reaches the adjacent planting modules on the lower part, and is irrigated downwards in turn in the same way. The distance between the lower parts of the first overflow port, the second overflow port and the upper port of the third overflow port and the middle plate is 3-5 mm, so that water with the height of 3-5 mm can be stored in the first cavity, the situation that plants in the upper layer are too dry to cause water shortage in the planting cavity is prevented, water exceeding the height flows out of the overflow ports and irrigates downwards, and excessive water in the planting cavity on the upper layer is prevented from being harmful to respiration of plant roots.

Fig. 7 is a schematic structural view of a second embodiment of the planting container according to the present invention, and referring to fig. 7, the present embodiment is different from the first embodiment shown in fig. 5 in that: the planting container further comprises a binding 300 and a water tank 400, wherein the binding 300 is arranged at the edge of the planting container, so that the planting container can be further stabilized, and the splicing module 100 is prevented from loosening; a water tank 400 is provided below the planting container for holding water overflowed from the planting container, preventing the water from wetting the ground, and storing irrigation water, and the water in the water tank 400 is delivered into the planting chamber 200 for irrigation by connecting a water delivery device (not shown). And a moving device can be arranged, for example, a roller device is arranged below the planting container, so that the planting container is wholly movable, a movable green wall is formed, and the position can be flexibly adjusted.

Fig. 8 is a schematic structural diagram of one embodiment of the edge covering and water tank in the embodiment shown in fig. 7, and fig. 9 is an exploded view of fig. 8, and referring to fig. 8 and 9, the edge covering 300 includes a plurality of frames 310 and a plurality of connectors, and the frames 310 and the connectors are spliced with each other to form the edge covering 300. The connecting bodies include a first connecting body 320 and a second connecting body 330, the first connecting body 320 includes a first connecting portion 321 symmetrically arranged for being clamped with the end portion of the frame 310, the first connecting body 320 is used for splicing adjacent frames 310 on the same edge, the second connecting body 330 includes a second connecting portion 331 symmetrically arranged for being clamped with the end portion of the frame 310, and the second connecting body 330 is used for splicing the frames 310 at the adjacent edges, so that the adjacent frames 310 form a certain angle. In this embodiment, the planting container is integrally rectangular, so the edge covering 300 is a rectangular frame structure arranged along the edge of the planting container, the edge covering 300 is arranged on two sides and the upper edge of the planting container, the first connecting body 320 is used for splicing adjacent frames 310 on the same edge, and the second connecting body 330 is used for clamping the frames 310 on the adjacent edges at right-angle turning positions. The first connector 320 and the second connector are further provided with a fixing portion 340, and when the planting container includes a plurality of splicing modules and the overall length or height is large, fixing screws can be driven into the mounting surface such as the wall surface through the fixing portion 340, so that the planting container is fixed.

The lower border of planting container is provided with basin 400, and basin 400 includes cell body 410 and concatenation body 420, and in this embodiment, cell body 410 and concatenation body 420 splice each other and form basin 400, and the concatenation body includes first concatenation body 421 and second concatenation body 422, and the symmetry is provided with first draw-in groove on the first concatenation body 421 for with adjacent cell body 410 joint, be provided with the second draw-in groove on the second concatenation body 422, be used for with cell body 410 and bordure 300 joint. The water tank of this embodiment includes two tank bodies 410, a first splicing body 421 and two second splicing bodies 422, where the two second splicing bodies 422 are respectively clamped with two sides of the covered edge 300.

The planting container can select the number of the splicing modules, the splicing height, the shape and the like according to specific requirements, the splicing modules are mutually spliced and fixed, when the splicing height is lower, the planting container can be fixed through the splicing fonts among the splicing modules without arranging a fixing device, and the planting container can simplify the structure and is flexible and convenient to assemble and disassemble; when the splicing height exceeds the set height, the covering frame can be correspondingly arranged, and the planting container is fixedly installed on a corresponding wall body or other installation planes through the fixing pin penetrating through the fixing hole on the backboard. The planting container is suitable for being attached to or fixedly mounted on a plane or a micro-curved surface, forms a vertical planting container, has small occupied area, can be freely spliced, can be adjusted according to specific mounting environments, has high flexibility, has good landscape and ecological benefits, and is suitable for various places such as indoor or outdoor places.

The present invention is not limited to the above-described preferred embodiments, but various equivalent modifications and substitutions can be made by those skilled in the art without departing from the spirit of the present invention, and these equivalent modifications and substitutions are intended to be included in the scope of the present invention as defined in the appended claims.

Claims (9)

1. A splice module, characterized in that: the splicing module is provided with a first splicing part, a second splicing part, a third splicing part and a fourth splicing part, and the first splicing part, the second splicing part, the third splicing part and the fourth splicing part are positioned at the periphery of the splicing module and are respectively used for splicing another splicing module adjacent to the corresponding direction of the splicing module; wherein,,

the splicing module comprises a back plate, a middle plate, a pair of symmetrical first side walls and a pair of symmetrical second side walls, wherein the first side walls and the second side walls are perpendicular to the back plate, the middle plate is arranged between the first side walls and the second side walls and perpendicular to the back plate, the middle plate, the back plate and the first side walls jointly enclose a first cavity, and the middle plate, the back plate and the second side walls jointly enclose a second cavity;

the first splicing part is arranged on the upper part of the first side wall, the second splicing part is arranged on the lower part of the second side wall, the first splicing part comprises a pair of first splicing surfaces and a pair of mounting grooves, the second splicing part comprises a pair of second splicing surfaces and a pair of mounting ribs, the mounting grooves are used for being clamped with the mounting ribs on the adjacent splicing modules, and the mounting ribs are used for being clamped with the mounting grooves on the adjacent splicing modules;

the third splicing part and the fourth splicing part are respectively arranged at two sides of the backboard;

the first splicing surface, the second splicing surface, the first side wall, the second side wall and the backboard corresponding to one side of the third splicing part jointly enclose a third cavity; the first splicing surface, the second splicing surface, the first side wall, the second side wall and the backboard corresponding to one side of the fourth splicing part jointly enclose a fourth cavity;

the first cavity, the second cavity, the third cavity and the fourth cavity are respectively used for planting plants, an overflow port is arranged in the first cavity and used for discharging redundant water in the first cavity into the second cavity, the third cavity and the fourth cavity respectively.

2. The splice module of claim 1, wherein: the third splice is the buckle structure, the fourth splice is the card hole structure, the buckle structure be used for with on the adjacent splice module the cooperation lock joint of card hole, the card hole structure be used for with on the adjacent splice module the cooperation lock joint of buckle structure.

3. The splice module of claim 1 or 2, wherein: the first side wall and the second side wall are provided with a plurality of vent holes.

4. The splice module of claim 1 or 2, wherein: the first side wall and the middle plate are arranged at an obtuse angle, and the second side wall and the middle plate are arranged at an obtuse angle.

5. The splice module of claim 1 or 2, wherein: the novel solar cell module comprises a back plate, and is characterized by further comprising a front plate, wherein the front plate is parallel to the back plate, the first side wall, the second side wall and the middle plate are arranged between the front plate and the back plate, and notches are respectively arranged on the front plate at positions corresponding to the first cavity and the second cavity.

6. The splice module of claim 1, wherein: the pipeline device further comprises a guide groove used for penetrating the pipeline, and the guide groove is arranged at the upper part of the first side wall.

7. A planting container, characterized in that: comprising a number of splice modules according to any one of claims 1 to 6, adjacent ones of said splice modules being spliced to each other by said first splice, said second splice, said third splice and said fourth splice.

8. The planting container of claim 7, wherein: the planting container is characterized by further comprising a wrapping edge arranged on the edge of the planting container, wherein the wrapping edge comprises a plurality of frames and a plurality of connectors, and the frames and the connectors are mutually spliced to form the wrapping edge.

9. The planting container of claim 7, wherein: still include the basin, the basin sets up in planting container's lower part, the basin includes cell body and concatenation body, the cell body with the concatenation body splices each other and forms the basin.