JP2007215405A - Cultivation system, soil-charged container for the cultivation system, and knock-down planter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cultivation system with which even a nonexpert can easily cultivate vegetables and plants/flowering plants at her (his) home garden. <P>SOLUTION: The cultivation system comprises a soil-charged net 210 the inside of which is freely filled with a prescribed kind of soil M and surplus water in the soil M charged in the inner part of which is freely discharged, and a management tag 215 showing attribution of the soil M to be charged in the soil-charged net 210. The management tag 215 is correlated with the soil-charged net 210 charged with the soil M at a relation rate of 1:1 to manage the soil-charged net 210 charged with the soil M by the management tag 215. The soil M is housed in a gardening container together with the soil-charged net 210 to cultivate plants on the soil M charged in the soil-charged net 210. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a garden cultivation system, a soil filling container for a cultivation system, and an assembly-type planter.

In general, garden containers such as flower pots and planters are used to grow plants such as flowering trees. In addition, as a gardening container, an assembly-type gardening container has been proposed because it can be easily transported and carried, or can be stored without being bulky. As a conventional garden container of this type, for example, there is a technique described in Patent Document 1.
JP-A-7-227147

  Patent Document 1 discloses a horticultural container that includes a flat bottom plate and a side plate and a frame having a fitting groove, and is assembled by fitting the bottom plate and the side plate into the fitting groove of the frame. Has been. A drain hole is formed in the bottom plate. Moreover, the tapping screw is inserted into the screw hole formed in each member, and each member is firmly fixed by using a screwdriver.

  However, since the technique described in Patent Document 1 uses a garden container alone, after assembling the garden container, the user himself selects the soil suitable for the plant desired to be cultivated and fills the garden container. Then, after that, the troublesome and experienced work similar to a gardening container such as a normal planter is naturally required to plant plants such as flowering trees corresponding to the soil. That is, the user needs a series of operations for purchasing commercially available plants such as flowers, plants, flowers, and seedlings, and planting the plants on the soil in the gardening container. Moreover, when a user needs to change a gardening container to a bigger thing etc. with the growth of a plant, a considerable effort is required for the change work (pot change work). Furthermore, since the horticultural container of Patent Document 1 is assembled by a large number of members, the assembling work becomes complicated. In addition, since the gardening container of Patent Document 1 uses screws as fixing means, it cannot be assembled without a tool such as a screwdriver. Furthermore, the gardening container of Patent Document 1 has a net-like gardening floor placed on the drain hole in the bottom wall in order to prevent the soil from flowing out and to discharge excess water in the soil. Or laying pot-bottom stones on the bottom wall, the outside air is hardly supplied inside the gardening container.

  Therefore, the present invention eliminates the need for selecting a soil suitable for the plant for the cultivation of plants such as vegetables, flowers, and vegetation, and for selecting a plant such as a flowering tree corresponding to the soil. However, it is possible to easily cultivate vegetables, grow plants and flowers, and change gardening containers (pot changing work) very easily. In addition to the cultivation system and cultivation system that can perform management easily, and can drastically improve the growth of plants by greatly increasing the efficiency of supplying outside air to the soil and draining the surplus water of the soil. An object is to provide a soil filling container and an assembling planter.

  The cultivation system according to the present invention represents a soil-filling container that can be filled with a predetermined type of soil, and can drain excess water of the soil filled therein, and an attribute of the soil that fills the soil-filling container. The management tag is associated with the soil filling container filled with soil in a one-to-one relationship, the soil filling container filled with the soil is managed by the management tag, and the soil is The soil filling container is housed inside the horticultural container, and the plant is grown using the soil filled in the soil filling container.

  In addition, the soil filling container of the cultivation system according to the present invention is formed into a container that can be filled with a predetermined type of soil, and can be used to drain excess water of the soil filled inside, and filled with the soil. It can be stored in the garden container in a state.

  Furthermore, the assembling-type planter of the cultivation system according to the present invention includes three or more flat plate-like side walls that can be connected to and separated from each other at the left and right side edges, and a cylindrical body by connecting the three or more side walls. A bottom wall that is placed on the bottom of the cylindrical body and a connecting rod that maintains the connection between the connected side walls, and a plurality of connecting pieces are provided at the left and right ends of each side wall. It is formed integrally alternately so as to be staggered at the same arrangement interval as the size, and the connecting pieces on the adjacent side walls are engaged with each other and connected, and the insertion hole is formed in the axial direction of the connecting piece. When the connecting pieces on the adjacent side walls are engaged with each other, the connecting holes of the connecting pieces engaged with each other are connected in a straight line with the same non-circular cross-sectional shape, and the connecting rod is inserted into the inserting hole. As the non-circular cross-sectional shape identical to the cross-sectional shape of By mounting the insertion hole of the mutually meshing the connecting piece, so that to prevent relative movement and relative rotation between the side walls and the connecting by the connecting rod.

  Since the present invention is configured as described above, selection of a soil suitable for the plant for the cultivation of plants such as vegetables, flowers, and vegetation, and conventional troublesome work of selecting a plant such as a flowering tree corresponding to the soil. This makes it easy for amateurs to cultivate vegetables and grow plants and flowers, and can also change gardening containers (pot changing work) very easily. In addition, it is possible to easily execute management such as recycling and reuse, and in addition, it is possible to greatly improve plant growth by greatly increasing the efficiency of supplying outside air to the soil and draining the surplus water of the soil. In particular, a management tag representing the attribute of the soil to be filled in the soil filling container is associated with the soil filling container filled with the soil in a one-to-one relationship, and the soil filling container filled with the soil is managed by the management tag. Therefore, the producer selects a suitable soil for the plant to be grown, and provides the user (user) with the selected soil filled in the soil filling container, and the attribute of the soil (product number) , Producer, soil type, soil name, chemical composition, growable plant, fertilization method, etc.) can be indicated on the management tag so that the user can grow on the soil in the soil filling container obtained (cultivation is suitable) Plants can be selected easily. Alternatively, the producer performs seed sowing and raising seedlings on the soil, and provides the user (user) in that state, and the attributes of the soil and the plant (product number, producer, plant type, plant name, breeding method, By expressing the flowering time, fertilization method, etc.) on the management tag, the user can cultivate the plant very easily with the soil and plants (seed seedlings) in the soil filling container obtained. Thereby, the total cultivation system as one packaged product which an amateur user can perform a vegetable garden, a veranda gardening, etc. easily can be provided.

  Hereinafter, the best mode for carrying out the present invention (hereinafter referred to as an embodiment) will be described. Throughout the embodiments, the same members, elements, or parts are denoted by the same reference numerals and description thereof is omitted.

Embodiment 1
First, the assembly-type planter as a gardening container used with the cultivation system which concerns on Embodiment 1 of this invention is demonstrated. FIG. 1 is a perspective view showing an assembled state of an assembly-type planter as a horticultural container used in the cultivation system according to Embodiment 1 of the present invention. FIG. 2: is a figure which decomposes | disassembles and shows the structural member of the assembly-type planter used with the cultivation system which concerns on Embodiment 1 of this invention, (a) is the front view of a connecting rod, and the front view of a side wall in order from the left ( (Outer side view), Rear view of the side wall (inner side view), (b) is a top view of the side wall (viewed from the upper end side) and a bottom view of the side wall (viewed from the lower end side) ) Respectively.

  As shown in FIG. 1, the assembly type planter of the cultivation system of Embodiment 1 includes a pair of front and rear (two) side walls 10 having the same configuration, a pair of left and right (two) side walls 10A having the same configuration, and four identical ones. The connecting rod 31 and the bottom wall 40 are configured. The pair of front and rear side walls 10 have the same configuration (same shape and size), and the pair of left and right side walls 10A have the same configuration (same shape and size). As shown in FIG. 2, the side wall 10 has a flat plate portion 11 having a substantially thin rectangular plate shape. The flat plate portion 11 includes a plurality (six) of thin wall portions 12 that are formed in a substantially horizontally long rectangular flat plate shape. In addition, linear ribs 13 protrude and are integrally formed on the outer peripheral edge of the thin portion 12 of the flat plate portion 11. Specifically, the ribs 13 are formed continuously over the entire length of the upper edge and the left and right side edges of the flat plate portion 11, and extend between the ribs 13 on the left and right side edges in parallel with the ribs 13 on the upper edge. A plurality of ribs 13 are formed. The portion of the horizontally long rectangle surrounded by the rib 13 of the flat plate portion 11 is the thin portion 12. Furthermore, a handle portion 14 is provided in the upper portion of the flat plate portion 11, specifically, the second thin portion 12 from the top. The handle portion 14 has a hollow, horizontally long, rectangular box shape that is recessed inward from the outer surface of the thin portion 12 of the flat plate portion 11. The outer surface side is an opening 14 a, and the user opens the handle portion 14. The handle portion 14 can be hooked and held by inserting fingers from 14a. Note that the handle portion 14 may be formed integrally with the flat plate portion 11 or formed separately from the flat plate portion 11, and the outer peripheral surface of the handle portion 14 is disposed at a corresponding position of the thin portion 12 of the flat plate portion 11. It is also possible to form a fitting hole that can be fitted in a close state, and fix the handle portion 14 to the fitting hole by fitting, adhering, welding, or the like. A pair of leg portions 15 are integrally formed at both ends of the lower edge of the flat plate portion 11, and a concave portion 16 is formed between the both leg portions 15.

  As shown in FIG. 2, a plurality of connecting pieces 17 and 18 are alternately and integrally formed at the left end and the right end of the flat plate portion 11 so as to be alternately arranged at the same arrangement interval as the height dimension thereof. The connecting pieces 17 and 18 of the side walls 10 and 10A are engaged with each other and connected. Specifically, four connecting pieces 17 are integrally formed on the right edge (as viewed from the outer surface side) of the flat plate portion 11 at regular intervals from the upper end to the lower end. The interval between the connecting pieces 17 is set to be the same as the height (length) of the connecting pieces 17. That is, the four connecting pieces 17 are arranged side by side in the vertical direction at the same interval as the height thereof. Each connecting piece 17 is formed in a substantially rectangular parallelepiped block shape having a vertically long rectangular shape in a front view and a deformed quadrangular shape as shown in FIG. 2B in a plan view. Further, the outer side surface and the inner side surface of the connecting piece 17 are parallel to each other and are also parallel to the flat plate portion 11. Furthermore, the right side surface and the left side surface of the connecting piece 17 are parallel to each other and are orthogonal to the flat plate portion 11. The corner portion between the outer side surface and the right side surface of the connecting piece 17 and the corner portion between the inner side surface and the left side surface are curved surfaces having a predetermined radius of curvature (R), respectively. Further, each connecting piece 17 is formed with an insertion hole 17a having a substantially quadrant in section so as to extend linearly along the axis. Therefore, the insertion holes 17a of the four connecting pieces 17 communicate with each other in the vertical direction so as to be concentric along the same axis. Further, of the insertion holes 17a of the connecting piece 17, one of the two linear portions (radial portion of the quadrant arc) extends parallel to the flat plate portion 11 (parallel to the inner surface of the connecting piece 17), and the other is , Extending in a direction perpendicular to the flat plate portion 11 (parallel to the left side surface or the right side surface of the connecting piece 17). In the insertion hole 17 a of the connecting piece 17, the curved portion (circumferential portion of the quadrant arc) extends corresponding to the curved corner surface outside the connecting piece 17. Here, a circular fitting hole 17b surrounding the insertion hole 17a is formed in the lower end surface of the lowermost connecting piece 17. The inner bottom surface of the fitting hole 17b of the connecting piece 17 is a flat surface.

  On the other hand, three connecting pieces 18 are integrally formed on the left side edge (as viewed from the outer surface side) of the flat plate portion 11 at regular intervals from the upper end to the lower end. The connecting piece 18 has a substantially rectangular parallelepiped block shape that is symmetrical with the connecting piece 17 in the left-right direction. That is, the connecting piece 18 has the same configuration as the connecting piece 17 except that the connecting piece 18 is symmetrical. The three connecting pieces 18 are arranged at positions that completely correspond to the gap portions between the four connecting pieces 17 (alignment positions). Therefore, on the left side edge of the flat plate portion 11, there are no connection pieces 18 at positions corresponding to the uppermost and lowermost connection pieces 17 and at positions corresponding to the two connection pieces 17 in the central portion, respectively. On the other hand, at the right edge of the flat plate portion 11, there is no connecting piece 17 at a position corresponding to the connecting piece 18, and each is a gap portion. That is, the interval between the connecting pieces 18 is set to be the same as the height (length) of the connecting pieces 18, and the three connecting pieces 18 are arranged side by side in the vertical direction at the same interval as the height. . The outer side surface and the inner side surface of the connecting piece 18 are parallel to each other and to the flat plate portion 11. Further, the left side surface and the right side surface of the connecting piece 18 are parallel to each other and are orthogonal to the flat plate portion 11. The corner portion between the outer side surface and the left side surface of the connecting piece 18 and the corner portion between the inner side surface and the right side surface are curved surfaces having a predetermined radius of curvature (R), respectively. In addition, each connecting piece 18 is formed with an insertion hole 18a having a substantially quadrant in section so as to extend linearly along the axis. Therefore, the insertion holes 18a of the three connecting pieces 18 communicate in the vertical direction so as to be concentric along the same axis. Further, of the insertion holes 18 a of the connecting piece 18, one of the two linear portions (radial portion of the quadrant arc) extends parallel to the flat plate portion 11 (parallel to the inner surface of the connecting piece 18), and the other is , Extending in a direction orthogonal to the flat plate portion 11 (parallel to the right side surface or the left side surface of the connecting piece 18). In the insertion hole 18 a of the connecting piece 18, the curved portion (circumferential portion of the quadrant arc) extends corresponding to the curved corner surface outside the connecting piece 18.

  The uppermost connecting piece 17 is arranged corresponding to the right end of the uppermost thin portion 12 of the flat plate portion 11, and the second uppermost portion and the second uppermost portion corresponding to the upper and lower ends of the connecting piece 17. There are ribs 13 (extending in the left-right direction). In addition, the uppermost connecting piece 18 is arranged corresponding to the left end of the second thin portion 12 from the top of the flat plate portion 11, and the second from the top corresponding to the upper and lower ends of the connecting piece 18 and There is a third rib 13 (extending in the left-right direction). Further, the second connecting piece 17 from the top is arranged corresponding to the right end of the upper half of the third thin portion 12 from the top of the flat plate part 11, and corresponding to the upper end of the connecting piece 17, There is a third rib 13 (extending in the left-right direction) from the top. In addition, a second connecting piece 18 is arranged from the top corresponding to the left end of the lower half of the third thin portion 12 from the top of the flat plate portion 11, and corresponding to the lower end of the connecting piece 18, There is a fourth rib 13 (extending in the left-right direction) from the top. Further, a third connecting piece 17 from the top is arranged corresponding to the right end of the fourth thin portion 12 from the top of the flat plate part 11, and the four from the top corresponding to the upper and lower ends of the connecting piece 17. There are first and fifth ribs 13 (extending in the left-right direction). Further, the third connecting piece 18 from the top is arranged corresponding to the left end of the fifth thin portion 12 from the top of the flat plate portion 11, and the top 5 corresponding to the upper and lower ends of the connecting piece 18. There are first and sixth ribs 13 (extending in the left-right direction). Further, the lowermost connecting piece 17 is arranged corresponding to the right end of the lowermost thin portion 12 of the flat plate portion 11, and the lowermost (extending in the left-right direction) rib corresponding to the upper end of the connecting piece 17. 13 exists. Note that the lower end of the lowermost connecting piece 17 coincides with the lower end of the leg portion 15, and the lower end surface of the leg portion 15 and the lower end surface of the connecting piece 17 become a flat surface that is flush with each other, which will be described later. Thus, when the assembly type planter is assembled, a support surface for the mounting surface of the assembly type planter is configured in cooperation. Here, the third thin portion 12 from the top of the flat plate portion 11 is set to be twice as wide as the other thin portions 12. This is for a predetermined display. Therefore, of course, the third thin portion 12 from the top of the flat plate portion 11 is vertically divided into two, and each of the divided portions has the same width as the other thin portions 12. In the center of the width direction (height direction), a horizontally extending rib 13 may be provided. In this case, except for the lower end of the lowermost connecting piece 17, ribs 13 extending horizontally are present at the upper and lower ends of all the connecting pieces 17, 18, respectively.

  A plurality of linearly extending ridges 19 extending in the vertical direction are integrally formed on the inner surface of the flat plate portion 11 so as to be parallel to each other at regular intervals and to protrude inward perpendicularly to the flat plate portion 11. Has been. Specifically, the protrusion 19 has a linear protrusion shape or a rib shape extending from the upper end edge of the flat plate portion 11 to the vicinity of the lower end edge. Further, a total of four ridges 19 are integrally formed at a constant interval in the width direction of the back surface of the flat plate portion 11. Furthermore, although the protrusion amount of the protrusion 19 can be set as appropriate, in the illustrated example, the protrusion amount is about a half of the protrusion amount of the connecting sides 17 and 18 from the flat plate portion 11. In addition, the protrusion 19 comprises the air supply path formation means in the cultivation system of this invention in cooperation with the soil filling container mentioned later. On the other hand, a strip-like support piece 20 is integrally formed on the lower edge of the flat plate portion 11 so as to protrude inward perpendicular to the flat plate portion 11. In FIG. 2, the support piece 20 protrudes from the flat plate portion 11 with a protruding amount smaller than the protruding amount of the connecting pieces 17 and 18 from the flat plate portion 11. Further, in FIG. 2, the support piece 20 is a flat plate with a protruding amount that is slightly more than a half of the protruding amount of the connecting pieces 17 and 18 from the flat plate portion 11, that is, a protruding amount slightly larger than the protruding amount of the protrusion 19. Projecting from the portion 11. Therefore, the insertion piece 21 for the vine support rod is integrally formed at the upper end of the inner side surface of the flat plate portion 11 of the incidental change 20 adjacent to the connecting piece 17. The insertion piece 21 is formed with a circular hole 21a having a diameter corresponding to the diameter of the vine support rod standing and used for supporting the vine so as to extend linearly along its axis. .

  The pair of left and right side walls 10A of the assembly type planter is different from the side wall 10 in that the width dimension (dimension in the left and right direction) is larger than that of the side wall 10 and the handle portion 14 is not provided. The configuration is the same. Specifically, the pair of left and right side walls 10 </ b> A has a flat plate portion 11 </ b> A having a substantially horizontally long rectangular shape as in the case of the side wall 10. As in the case of the thin portion 12 of the flat plate portion 11, the flat plate portion 11 </ b> A includes a plurality of (six) thin portion 12 </ b> A having a substantially horizontally long flat plate shape arranged vertically. Further, as in the case of the ribs 13 of the flat plate part 11, the linear ribs 13A protrude and are integrally formed on the outer peripheral edge of the thin part 12A of the flat plate part 11 and are surrounded by the ribs 13A of the flat plate part 11A. Is the thin-walled portion 12A. In addition, the handle part 14 is not provided in the thin part 12A of the flat plate part 11A. And, as in the case of the flat plate portion 11, four connecting pieces 17 are integrally formed on the right side edge (as viewed from the outer surface side) of the flat plate portion 11A from the upper end to the lower end at a constant interval. The three connecting pieces 18 are integrally formed at regular intervals from the upper end to the lower end. On the other hand, on the inner surface of the flat plate portion 11A, as in the case of the flat plate portion 11, a plurality of linearly extending ridges 19 extending in the vertical direction are parallel to each other at regular intervals and orthogonal to the flat plate portion 11A. Thus, it is integrally formed so as to protrude inward. Specifically, the protrusion 19 has a linear protrusion shape or a rib shape extending from the upper end edge of the flat plate portion 11A to the vicinity of the lower end edge. Further, a total of six ridges 19 are integrally formed at a constant interval in the width direction of the back surface of the flat plate portion 11A. Furthermore, although the protrusion amount of the protrusion 19 can be set as appropriate, in the illustrated example, the protrusion amount is about a half of the protrusion amount of the connecting sides 17 and 18 from the flat plate portion 11A. In addition, the protrusion 19 comprises the air supply path formation means in the cultivation system of this invention in cooperation with the soil filling container mentioned later. On the other hand, as in the case of the flat plate portion 11, the support piece 20 is integrally formed on the lower edge of the flat plate portion 11 </ b> A. As in the case of the insertion piece 21 of the flat plate portion 11, the insertion piece 21 for the vine support rod is integrally formed at the upper end of the inner surface of the flat plate portion 11 </ b> A adjacent to the connection piece 17.

  The connecting rod 31 is formed by integrally forming a disc-shaped head portion 31a and a linear rod-shaped shaft portion 31b extending downward from the lower surface of the head portion. The head 31a of the connecting rod 31 has a circular disk shape that is the same as the circular fitting hole 17b at the lower end of the connecting piece 17, and can be inserted into the fitting hole 17b of the connecting piece 17 in a substantially tightly fitted state. It is like that. In addition, the shaft portion 31b of the connecting rod 31 has a bar shape having the same cross-sectional shape as the insertion holes 17a and 18a of the connecting pieces 17 and 18, that is, a straight bar shape having a quadrant arc. Further, the shaft portion 31 b of the connecting rod 31 has the same length as the length from the upper end surface of the uppermost connecting piece 17 to the lower end surface of the lowermost connecting piece 17. Further, the bottom wall 40 is constructed by assembling the pair of front and rear side walls 10 and the pair of left and right side walls 10A into a rectangular cylindrical shape by engaging adjacent connecting pieces 17 and 18 with each other as shown in FIGS. When connected to each other by the four connecting rods 31, a substantially rectangular flat plate shape corresponding to a rectangle formed by the lower ends of the inner side surfaces of the four side walls 10, 10 a is formed. In addition, curved notches 41 corresponding to the curved surfaces (curved corner surfaces) inside the connecting pieces 17 (particularly the lowermost connecting pieces 17) are formed at the four corners of the bottom wall 40, respectively. ing. Further, on the four sides (front and rear side edges and left and right side edges) of the bottom wall 40, there are formed short grooves corresponding to the cross-sectional shape of the ridges 19, and the accommodation grooves 42 that can accommodate the ridges 19 are formed. ing. That is, four receiving grooves 42 are formed on the front and rear side edges of the bottom wall 40 at the same interval as the protrusions 19 of the side wall 10, and the side walls 10 </ b> A are projected on the left and right side edges of the bottom wall 40, respectively. Six receiving grooves 42 are formed at the same interval as the strip 19. Here, as will be described later, the width and length of the bottom wall 40 (the horizontal dimension and the longitudinal dimension) are the tips of the protrusions 19 on the inner side surfaces of the four side walls 10 and 10A in the assembled state shown in FIG. It is set to a size approximately equal to or slightly larger than the rectangle determined by the position. That is, the width (left-right dimension) of the bottom wall 40 is set to a dimension that is approximately the same as or slightly larger than the dimension (left-right space dimension) between the tips of the protrusions 19 of the left and right side walls 10A facing each other. The length of the bottom wall 40 (front-rear direction dimension) is set to a dimension that is approximately the same as or slightly larger than the dimension (front-rear space dimension) between the tips of the protrusions 19 of the front and rear side walls 10 facing each other.

  Next, the assembly method of the assembly-type planter as a gardening container used with the cultivation system which concerns on Embodiment 1 of this invention is demonstrated. FIG. 3 is a front view for explaining the connection process between the side walls during assembly of the assembly-type planter used in the cultivation system according to Embodiment 1 of the present invention. FIG. 4 is a perspective view (corresponding to FIG. 3) for explaining a connection process between the side walls during assembly of the assembly-type planter used in the cultivation system according to Embodiment 1 of the present invention. FIG. 5 is a perspective view for explaining the insertion process of the connecting rod after connecting the four side walls during assembly of the assembly type planter used in the cultivation system according to Embodiment 1 of the present invention. FIG. 6 shows the assembly of the assembling-type planter used in the cultivation system according to Embodiment 1 of the present invention. After the four side walls are connected and fixed by the connecting rods in FIG. It is a perspective view which shows the process to perform.

  To assemble the assembly type planter of the first embodiment, first, two identically configured side walls 10, two identically configured side walls 10A, four identically configured connecting rods 31, and one bottom A wall 40 is prepared. Next, as shown in FIGS. 3 and 4, the connecting pieces 17 and 18 of the pair of front and rear side walls 10 and the pair of left and right side walls 10 </ b> A are arranged in an orthogonal state at the same height position. 17 and 18 are arranged so that one adjacent one faces the other gap portion, and the adjacent connecting piece 17 and connecting piece 18 are engaged with each other and connected, and the four side walls 10 and 10A are connected to each other as shown in FIG. It is set as the connection state shown in (rectangular cylinder shape). For example, the connecting piece 17 at the right end of the front side wall 10 and the connecting piece 18 at the left end of the right side wall 10 </ b> A are made to correspond to each other, and then closely approach each other. Next, the connecting piece 17 at the right end of the right side wall 10 </ b> A and the connecting piece 18 at the left end of the rear side wall 10 are made to correspond to each other, and then closely approach each other. Next, the connecting piece 17 at the right end of the side wall 10 on the rear side and the connecting piece 18 at the left end of the left side wall 10 </ b> A are made to correspond to each other, and then closely approach each other. Next, the connecting piece 17 at the right end of the left side wall 10 </ b> A and the connecting piece 18 at the left end of the front side wall 10 are made to correspond to each other, and then closely approach each other. Then, as shown in FIG. 5, the pair of front and rear side walls 10 and the pair of left and right side walls 10 </ b> A are assembled to form a rectangular cylindrical shape orthogonal to each other by meshing connection between the adjacent connection pieces 17 and connection pieces 18. .

  Here, at this time, the side wall 10 and the side wall 10A can freely rotate with respect to each other, and can be displaced and detached. Therefore, as shown in FIG. 10A is connected to each other so that they cannot rotate and cannot be separated from each other. Specifically, in the state of FIG. 5, the connecting piece 17 and the connecting piece 18 that mesh with each other between the side wall 10 and the side wall 10 </ b> A are in the form of a single straight bar whose cross-sectional shape (quarter arc shape) is aligned, The insertion hole 17a of the connecting piece 17 and the insertion hole 18a of the connecting piece 18 are arranged in a single (concentric) straight through hole shape whose cross-sectional shape (quarter arc shape) is aligned. Therefore, the connecting piece 17 that communicates the shaft portion 31b of the connecting rod 31 having the same cross-sectional shape (quarter arc shape) as the insertion holes 17a and 18a (straight through holes) of the connecting pieces 17 and 18 in the same cross section in the vertical direction. , 18 are inserted into the insertion holes 17a, 18a from above. Specifically, with respect to the seven connecting pieces 17 and 18 meshing with each other on the adjacent side walls 10 and 10A, the connecting pieces 31 are sequentially connected from the uppermost connecting piece 17 to the lower connecting pieces 18 and 17. It inserts into those insertion holes 17a, 18a, 17a, 18a, 17a, 18a, 17a from the upper direction toward 18, 17, 18, 17. When the head portion 31a at the upper end of the shaft portion 31b of the connecting rod 31 comes into contact with the upper end surface of the uppermost connecting piece 17, the shaft portion 31b enters the insertion holes 17a and 18a of the connecting pieces 17 and 18. Fully inserted. Similarly, the shaft of the connecting rod 31 is inserted into the insertion holes 17a, 18a of all the (four places) engaging pieces 17, 18 engaging each other (a set of seven connecting pieces 17, 18 in the form of a straight bar). The portion 31b is inserted, and the connecting rod 31 is inserted into a set of four connecting pieces 17 and 18 in total. As a result, the rotation between the side walls 10 and 10A adjacent to the connecting piece is achieved by the shaft portion 31b of the connecting rod 31 having a quadrangular cross section inserted into the insertion holes 17a and 18a of the connecting pieces 17 and 18 meshing with each other. The movement is completely restricted and prevented, and the four side walls 10 and 10A maintain the rectangular cylindrical shape (the final assembled state shape) of FIG.

  Next, as shown in FIG. 6, the bottom wall 40 is dropped into the internal space between the side walls 10, 10 </ b> A from above and placed and supported on the support piece 20. That is, the bottom wall 40 is inserted into the rectangular opening formed at the upper ends of the four side walls 10 and 10A having a rectangular tube shape in an inclined state. (For example, the front end) is placed on the support piece 20 of the corresponding side wall 10, 10A. At this time, the notches 41 at both ends of the one end of the bottom wall 40 accommodate the curved corner surfaces of the inner surfaces of the lowermost connecting pieces 17 at both ends of the corresponding side walls 10, 10 </ b> A, and the accommodation grooves 42 of the bottom wall 40. However, since the protrusions 19 on the inner surfaces of the corresponding side walls 10 and 10A are accommodated, the bottom wall 40 does not interfere with the connecting piece 17 and the protrusions 19. Thereafter, the other end (rear end) in the length direction of the bottom wall 40 is placed on the support piece 20 of the opposite side wall 10, 10A. At this time, the notch portions 41 at both ends of the other end of the bottom wall 40 accommodate the curved corner surfaces of the inner surfaces of the lowermost connecting pieces 17 at both ends of the corresponding side walls 10, 10 </ b> A, and the accommodation grooves of the bottom wall 40. Since 42 accommodates the protrusion 19 on the inner surface of the corresponding side wall 10, 10 </ b> A, the bottom wall 40 does not interfere with the connecting piece 17 or the protrusion 19. At the same time, the remaining two sides (both ends in the width direction) of the bottom wall 40 are placed on the support pieces 20 at corresponding positions of the side walls 10 and 10A. At this time, the receiving grooves 42 on the two sides of the bottom wall 40 receive the protrusions 19 on the inner surfaces of the corresponding side walls 10, 10 </ b> A, so that the bottom wall 40 does not interfere with the protrusions 19. In this way, the bottom wall 40 is completely accommodated inside the four side walls 10 and 10A having a rectangular tube shape, and the bottoms are placed on the four support pieces 20 protruding in a direction not from the lower end of the inner side surface of the side walls 10 and 10A. The wall 40 can be placed and supported. At this time, the width and length of the bottom wall 40 are the same as the dimension between the tips of the ridges 19 of the left and right side walls 10A (horizontal interval) and the dimension between the tips of the ridges 19 of the front and rear side walls 10 (front and rear intervals). The four sides of the bottom wall 40 are set on a support piece 20 that is set to a certain size or a slightly larger size and further protrudes inward from the ridges 19 via a notch 41 and a receiving groove 42 formed in the bottom wall 40. Can be smoothly placed. As described above, when the bottom wall 40 is inclined and inserted into the side walls 10 and 10A, interference of the handle portion 14 protruding from the side walls 10 and 10A (with a larger projection amount than the support piece 20) is prevented. be able to.

  Here, when the protruding amount of the handle portion 14 is made smaller than the protruding amount of the support piece 20, the bottom wall 40 is dropped into the side walls 10, 10 </ b> A at a time without tilting the bottom wall 40, and onto the support piece 20. It is also possible to place them at once. Alternatively, as shown in FIGS. 7 and 8, the bottom wall 40 is formed with four sides in a straight line without forming the receiving grooves 42 on the four sides (front and rear, left and right edges), and the inside of the side walls 10, 10 </ b> A. It is also possible to adopt a configuration for placing on the support piece 20. FIG. 7: is a top view (figure seen from the upper surface side) which shows the assembly state of the assembly-type planter used with the cultivation system which concerns on Embodiment 1 of this invention. 8 is a cross-sectional view taken along line AA in FIG. In this case, even if one of the width or length of the bottom wall 40 is slightly larger than the interval between the tips of the ridges 19 in the side walls 10 and 10A (left-right interval and front-rear interval), the lower end of the ridges 19 is supported. By providing an interval equal to or greater than the thickness of the bottom wall 40 between the piece 20 and the edge 20 (front and rear edge or left and right edge), the bottom edge of the protrusion 19 and the support piece 20 The bottom wall 40 can be placed on the support piece 20 by being inserted into the gap between the two. Alternatively, in the case of the example of FIG. 8, as described above, if the receiving grooves 42 are formed on the four sides of the bottom wall 40, both the width and the length of the bottom wall 40 can be reduced by the protrusion 19 inside the side walls 10, 10 </ b> A. Even if it is slightly larger than the distance between the tips (left-right distance and front-back distance), the end of the bottom wall 40 can be provided even if there is no gap greater than the thickness of the bottom wall 40 between the lower end of the protrusion 19 and the support piece 20. Edges (front and rear end edges and left and right end edges) can be placed on the support piece 20. Alternatively, the protruding amount of one of the support pieces 20 (for example, one of the support pieces 20 of the front and rear side walls 10) is made considerably larger than the above example, and is inward from the lower end opening between the side walls 10 and 10A. While projecting to a considerable extent, the corresponding side (front end portion or rear end portion) of the bottom wall 40 is cut larger than in the case of the above example corresponding to the projecting amount of the support piece 20. For example, the end portion of the bottom wall 40 is cut by the size of about half of the notch portion 41 of the bottom wall 40 or the entire size of the notch portion 41, and the interval between the front ends of the support pieces 20 of the front and rear side walls 10 is such a bottom wall. One support piece 20 (the support piece 20 corresponding to the cut end portion of the bottom wall 40) is protruded with a larger protrusion amount than the other support piece 20 so as to have a dimension larger than the length of 40 (front-rear direction dimension). In this way, the size of the bottom wall 40 can be made smaller than in the case of the above example, and the bottom wall 40 can be more smoothly inserted into the side walls 10 and 10A, and interference with the handle portion 14 can be prevented. Therefore, it is possible to reliably mount and support the device.

  As described above, by assembling and supporting the bottom wall 40 in the four side walls 10 and 10A connected by the connecting rod 31, the assembly of the assembly type planter of the first embodiment is completed. In such an assembled state, a plurality of assembly type planters can be stacked and stored vertically. At this time, the head 31a of the connecting rod 31 protruding from the upper end of the lower assembling planter (the upper end of the uppermost connecting piece 17) is located on the lower surface of the lowermost connecting piece 17 at the lower end of the upper assembling planter. The fitting hole 17b is housed and fitted in a close fitting state. As a result, a plurality of assembly-type planters can be stacked and stored in an orderly manner without being displaced from each other right and left. Further, the fitting hole 17b of the lowermost connecting piece 17 may not only accommodate the head portion 31a of the connecting rod 31, but also may be configured so that a rolling caster can be mounted. If it carries out like this, a caster will be mounted | worn in each fitting hole 17b of the connection edge 17 of the corner part of the four corners of the lower end of an assembly-type planter, and an assembly-type planter rolls easily via a caster, and becomes movable. In addition, the assembly type planter of Embodiment 1 can be used by filling it with soil (horticultural soil) as it is, but it is used in combination with a soil filling container as will be described later. It is preferable to do.

  FIG. 9 is a perspective view showing a first alternative assembly type planter (with the connecting rod and corner cover removed) used in the cultivation system according to Embodiment 1 of the present invention. As shown in FIG. 9, the assembly type planter of the 1st another example used with the cultivation system which concerns on Embodiment 1 is provided with the structure fundamentally the same as the assembly type planter of the example of FIGS. The four corners are different in that a corner cover 51 as a water leakage prevention cover is mounted. Specifically, the assembly planter of the first other example includes a pair of front and rear side walls 10 having the same configuration, a pair of left and right side walls 10A having the same configuration, four connecting rods 31 having the same configuration, and one bottom wall 40. In addition, four corner covers 51 having the same configuration are provided. Moreover, in the example of FIGS. 1-8, the outer surface of the connection pieces 17 and 18 of the side walls 10 and 10A is flush with the ribs 13 and 13A of the flat plate portions 11 and 11A. Although there is no step between 11A, in the example of FIG. 9, steps are formed between the outer surfaces of the connecting pieces 17, 18 of the side walls 10, 10A and the ribs 13, 13A of the flat plate portions 11, 11A. That is, in the example of FIG. 9, the connecting pieces 17 and 18 of the side walls 10 and 10A are made larger than the connecting pieces 17 and 18 of the examples of FIGS. And since the straight bar-shaped body LB is formed in the corner part of the side wall 10 and 10A of an assembly state by the total of seven connection pieces 17 and 18 as mentioned above, in the level | step-difference part thru | or step surface of the bar-shaped body LB. Both ends in the width direction of the corner cover 51 are elastically hooked so that the outside of the rod-shaped body LB can be completely covered. Thereby, even if water leaking from the soil inside the assembly type planter leaks from the meshing surface between the coupling piece 17 and the coupling piece 18 that are in meshing relationship, the corner cover 51 prevents such water leakage, The water leakage can be discharged below the assembly type planter along the inner surface of the corner cover 51. Note that, as described above, the rod-shaped body 31 is inserted into the through hole TH formed along the axis of the rod-shaped body LB.

  FIG. 10: is a bottom view (figure which looked at the assembly-type planter from the lower surface side) which shows the 1st example of the bottom wall of the assembly-type planter used with the cultivation system which concerns on Embodiment 1 of this invention. FIG. 11: is a bottom view (figure which looked at the assembly-type planter from the lower surface side) which shows the 2nd example of the bottom wall of the assembly-type planter used with the cultivation system which concerns on Embodiment 1 of this invention. For convenience of explanation, the bottom wall 40 of the assembly type planter according to the first embodiment is configured such that the drainage holes are not shown in FIGS. 6 to 8, but actually, for example, as shown in FIG. 10 or FIG. , 40b. That is, in the example of FIG. 10, two large-diameter circular drainage holes 40 a are formed before and after the central portion of the bottom wall 40. In the example of FIG. 11, a total of twelve small-diameter circular drain holes 40b are formed in a matrix in the entire bottom wall 40. Besides this, the drain hole can be formed in the bottom wall 40 in an arbitrary manner. Moreover, in Embodiment 1, the drain holes 40a and 40b of the bottom wall 40 are covered with, for example, a garden container floor (bottom net) shown in FIG. The soil filled in the planter is prevented from falling from the drain holes 40a, 40b of the bottom wall 40.

  FIG. 12 is a perspective view showing a second alternative assembly type planter used in the cultivation system according to Embodiment 1 of the present invention. FIG. 13: is sectional drawing which shows the state which piled up the assembly type planter of the 2nd another example used with the cultivation system which concerns on Embodiment 1 of this invention. The assembled planter shown in FIGS. 1 to 11 has a rectangular parallelepiped box shape in which the entire shape after assembly is open at the upper end, but as shown in FIG. 12, the second type used in the cultivation system according to the first embodiment. Another example of the assembly-type planter has an inverted quadrangular truncated pyramid shape with a narrowed lower end and a hollow square box shape with an open upper end. Therefore, the assembly type planter of the second alternative example is slightly changed in the basic configuration of each part (element) in order to obtain such an external shape. In detail, the assembly type planter of 2nd another example is the same as the assembly type planter of FIGS. 1-8, the pair of front-and-back side walls 110 of the same structure, the pair of left and right side walls 110A of the same structure, and four of the same structure. Connecting rod 131 and one bottom wall 40 are provided. The side wall 110 has an inverted trapezoidal plate shape. Further, as in the case of the side wall 10, the side wall 110 is integrally formed with the flat plate portion 111 by the thin portion 112 and the rib 113, but the thin portion 112 and the rib 113 have a shape corresponding to the inverted trapezoidal shape of the side wall 110. (The shape becomes narrower at the lower side). Further, on the inner surface of the side wall 110, (four) protrusions 119 similar to the protrusions 19 on the side wall 10 are integrally formed. Note that the connecting pieces 17 and 18 are integrally formed at the left and right ends of the side wall 110 as in the case of the side wall 10. On the other hand, the side wall 110A has an inverted trapezoidal plate shape. Further, as in the case of the side wall 10A, the side wall 110A integrally forms the flat plate portion 111A with the thin portion 112A and the rib 113A. However, the thin portion 112A and the rib 113A have a shape corresponding to the inverted trapezoidal shape of the side wall 110A. (The shape becomes narrower at the lower side). Further, on the inner surface of the side wall 110A, (six) ridges 119 similar to the ridges 19 on the side wall 10A are integrally formed. In addition, connecting pieces 17 and 18 are integrally formed at the left and right ends of the side wall 110A, as in the case of the side wall 10A. Further, the insertion piece 21 is integrally formed at the upper end of the inner side surface of the side walls 110 and 110A, and the leg portion 15 and the support piece 20 are integrally formed at the lower end of the inner side surface.

  Here, the side wall 110A and the side wall 110A each have an inverted trapezoidal shape, and the side walls 110 and 110A are connected to each other at an inclination angle that matches the inclination angle of the left and right end edges. The connecting pieces 17 and 18 at both ends of the side wall 110A are also integrally formed so as to be inclined corresponding to the inclination angle. Then, the rod-shaped body LB formed when the connecting pieces 17 and 18 of the adjacent side walls 110 and 110A are engaged with each other is tilted corresponding to the tilt angle of the left and right side edges of the side wall 110, and the axis of the rod-shaped body LB. Through holes TH formed by insertion holes 17a and 18a formed along the side of the side wall 110 are also inclined corresponding to the inclination angle of the left and right side edges of the side wall 110. Further, the upper end surfaces of the connecting pieces 17 and 18 are inclined with respect to the axial center of the connecting pieces 17 and 18, and when the side wall 110 and the side wall 110A are connected to each other and assembled, the upper end surfaces of the connecting pieces 17 and 18 are It becomes a horizontal plane. Therefore, since the connecting rod 131 is mounted with the shaft portion inclined at the inclination angle in the through hole TH of the rod-shaped body LH, the shaft portion is inclined with respect to the head of the rod-shaped body 131 at the inclination angle. The head portion and the shaft portion of the rod-shaped body 131 are integrally formed. Accordingly, when the shaft portion of the rod-shaped body 131 is mounted in the through hole TH of the rod-shaped body LB formed by meshing the connecting pieces 17 and 18 of the adjacent side walls 110 and 110A, the lower surface of the head is the uppermost portion. It smoothly comes into close contact with the upper end surface of the connecting piece 17.

  As shown in FIG. 13, when the assembly type planter according to the second alternative is stacked and stored up and down, the upper assembly type planter is accommodated to the inside of the lower assembly type planter and stacked. be able to. That is, according to the inclination angle of the left and right side edges of the side walls 110, 110A, the tips of the ribs 113, 113A on the outer surface of the side walls 110, 110A of the upper assembling planter are the side walls 110, 110A of the lower assembling planter. Since it cannot be moved downward due to contact with the tip of the protrusion 119 on the inner surface, the upper assembling planter can be accommodated and stacked inside the lower assembling planter. Alternatively, by increasing the inclination angle of the side walls 110 and 110A, or by providing the protrusion 119 only on the lower half of the inner surface of the side walls 110 and 110A and omitting it from the upper half, Widen the dimensions of the space, and the upper assembly planter leaves a part of the upper end in the lower assembly planter (for example, the upper part of the stepped portion that is a latching part of a typical planter). Can also be accommodated completely. That is, in this case, at the time of stacking, the tips of the lower ridges 119 on the inner surfaces of the lower assembly-type planter side walls 110, 110A and the tips of the ribs 113, 113A of the upper assembly-type planter side walls 110, 110A What is necessary is just to set the dimension of each part, etc. so that some space may be formed between.

  FIG. 14 is a perspective view showing a soil filling net as a soil filling container used in the cultivation system according to Embodiment 1 of the present invention. FIG. 15 is a perspective view showing a state (state during transportation) in which the soil is filled into the soil filling net used in the cultivation system according to Embodiment 1 of the present invention and the upper end opening of the soil filling net is narrowed. . In the cultivation system according to Embodiment 1, a soil filling net 210 as a soil filling container as shown in FIGS. 14 and 15 is used in combination with a horticultural container such as the assembly type planter or other ordinary planters. The soil filling net 210 includes a net portion 211, a reinforcement portion 212, a handle portion 213, and a fastening string 214, and can be filled with gardening soil therein. Specifically, the net portion 211 has a mesh shape of a predetermined mesh (unit of mesh roughness) having an opening at the upper end, and can be flexibly deformed into a desired shape. However, in the expanded state, as shown in FIG. The container has a rectangular container shape or a rectangular parallelepiped bag shape in which a substantially rectangular opening is formed at the upper end. The reinforcing portion 212 is fixed to the opening at the upper end of the net portion 211 by stitching, adhesion, welding or the like to form a belt shape that reinforces the opening portion at the upper end, has a certain degree of flexibility, and has strength such as a core material. It is made of material. Further, the reinforcing portion 212 is provided with a pair of left and right handle portions 213 integrally fixed to the left and right side portions thereof (portions corresponding to the left and right side portions of the net portion 211). Further, the reinforcing portion 212 is formed in a bag shape. Then, the fastening cord 214 is inserted into the reinforcement portion 212 from an insertion hole formed in a predetermined portion of the reinforcement portion 212 (for example, the central portion corresponding to the side surface of the net portion 211), and both end portions of the fastening cord 214 are inserted. Is taken out from the insertion hole of the reinforcing portion 212 to the outside. The fastening string 214 is formed of a normal string material, and by holding both ends of the fastening string 214 and fastening, the opening of the reinforcing part 212 and the opening of the net part 211 are held in a narrowed state. . And in the cultivation system of Embodiment 1, as shown in FIG. 15, predetermined | prescribed kind of soil is filled into the net | network part 211 from the upper end opening of the reinforcement part 212 of the soil filling net | network 210, and the fastening string 214 is fastened. Thus, the soil filling container 210 can be easily transported or carried via the pair of handle portions 213 with the openings of the reinforcing portion 212 and the net portion 211 narrowed.

  In addition, a management tag 215 is fixed to one end of the fastening string 214. In the management tag 215, information indicating the attributes / contents of the soil filled in the soil filling net 210 to which the management tag 215 is fixed, and the attributes / contents of plants suitable for the soil are displayed by printing or the like. . Specifically, the management tag 215 displays information indicating the type of soil, contents, chemical composition, type of properly cultivated plant, usable period, continuous cropping period, product number, etc. Information indicating the type, variety, name, flower color, leaf color, product number, variety registration number, etc., of plants (flowers, plants, fruit trees, vegetables, etc.) cultivated by the land used therein is displayed. Further, the management tag 215 can display and manage a one-dimensional barcode by printing or the like, or display and manage a two-dimensional barcode having a large amount of information as a barcode. In particular, when a barcode is displayed on the management tag 215 by printing or the like, it is possible to read detailed information (land attribute / content, plant attribute / content, plant, (Appearance photo, efficacy, cultivation method, cultivation time, etc.) can be displayed on the screen of the mobile phone, or the detailed information can be obtained by accessing the website displaying the detailed information. it can.

  FIG. 16: is a perspective view which shows the state which filled the soil inside the soil filling net | network used with the cultivation system which concerns on Embodiment 1 of this invention, and accommodated the soil filling net | network in the protection bag as a protective container. . As shown in FIG. 16, the soil filling net 210 is accommodated in a protective bag 220 having a corresponding bag shape. The protective bag 220 has a bag shape corresponding to the net part 211 and the reinforcing part 212 of the soil filling net 210 and is made of a bag material such as a plastic bag. Specifically, the protective bag 220 includes a storage part 221 having a rectangular bag shape with an upper end opened so as to cover the entire soil filling net 210, and left and right parts provided integrally with the upper ends of the left and right sides of the storage part 221. And a pair of handle portions 223. The handle portion 223 of the protective bag 220 is disposed at a position corresponding to the handle portion 213 of the soil storage net 210, and when the soil storage net 210 is stored in the storage portion 221, the handle portion 223 of the protective bag 220 and the soil storage are stored. The handle part 213 of the net 210 is arranged at the same position, and the user can grip the handle part 213 and the handle part 223 together. At this time, one end of the fastening string 214 of the soil filling net 210 is exposed to the outside from the upper end opening of the protective bag 220 so that the management tag 215 can be exposed to the outside.

  In the cultivation system according to the first embodiment, each type of soil is managed in a state of being filled in each of the different soil filling nets 210, distributed to the market, and used for the user. Alternatively, in the cultivation system of the first embodiment, as shown in FIG. 16, the soil filling net 210 is filled with a predetermined amount of soil M, and the soil filling net 210 is accommodated in the protective bag 220 in various states. The land M can be managed and distributed to the market, and can also be used by the user. The soil management and cultivation system using the soil filling container such as the soil filling net 210 and the management and cultivation system with the management tag 215 added thereto will be described in detail later.

  FIG. 17: is a perspective view which shows the state which filled the soil inside the soil filling net | network used with the cultivation system which concerns on Embodiment 1 of this invention, and accommodated the soil filling net | network in the assembly type planter. In the cultivation system of Embodiment 1, as shown in FIG. 17, the soil filling net 210 filled with soil is accommodated in the assembly type planter, and cultivation is carried out as it is. That is, in the cultivation system of Embodiment 1, the soil filling net 210 has a shape (substantially rectangular parallelepiped container shape) and dimensions (respective dimensions of front and rear, left and right, and height) corresponding to the internal space of the assembly type planter. Yes. The size of the soil filling net 210 is set such that when the soil filling net 210 filled with the soil is accommodated inside the assembly type planter, the upper end portion of the soil filling net 210 is exposed to the outside from the upper end portion of the assembly type planter. It is particularly preferable to set the height. If it carries out like this, the upper end part of the soil filling net | network 210 can be bent and arrange | positioned from the upper end of an assembly-type planter to the outer surface side, and the plant planted to the soil M in the soil filling net | network 210 can be managed easily. Of course, when the earth-filled net filling net 210 is accommodated in the assembly-type planter, the upper end of the earth-filling net 210 is flush with the upper end of the assembly-type planter and is not exposed to the outside. The dimensions of the filling net 210 can also be set. In this way, the soil filling net 210 is not exposed to the outside, and the influence of the soil filling net 210 on the design can be eliminated. However, as will be described later, it is also possible to impart designability, design or fashionability to the soil filling net 210 itself so as to improve the overall designability of the soil filling net 210. Furthermore, the management tag 215 can be exposed to the outside by exposing one end of the fastening string 214 of the soil filling net 210 from the upper end opening of the assembly type planter.

  FIG. 18 is a bottom view showing an example of a break line provided on the bottom surface of the protective bag used in the cultivation system according to Embodiment 1 of the present invention. FIG. 19 shows a process in which the soil filling net used in the cultivation system according to Embodiment 1 of the present invention is filled with the soil, and the soil filling net is accommodated in the assembly-type planter. Sectional drawing which shows the state accommodated in the assembly-type planter in the state which accommodated the filling net in the protection bag, seeing from the front side, (b) is the said protection bag fractured | ruptured by the broken line of a bottom face, and extracted from an assembly-type planter It is sectional drawing which shows a state seeing from the front side. In the cultivation system of the first embodiment, a broken line 222 made of perforations or the like is formed on the lower surface of the protective bag 220, the bottom surface of the protective bag 220 is easily broken through the broken line 222, and the protective bag 220 is filled with soil. It can be easily extracted (removed) from the net 210. Specifically, for cultivation with the cultivation system of the first embodiment, first, as shown in FIG. 19 (a), the soil filling net 210 filled with the soil M is accommodated in the protective bag 220, and they are stored. It is housed inside the assembly-type planter. Next, the handle portion 223 of the protective bag 220 is gripped, and the handle portion 223 is vigorously pulled toward the information (at a certain speed). Then, due to the weight of the soil M in the soil filling net 210, the soil filling net 210 is accommodated and held in the assembly type planter together with the soil M, and only the protective bag 220 is broken at the broken line 222 on the lower surface, and FIG. As shown in b), it is extracted upward. In this way, only the protective bag 220 can be removed from the assembly type planter.

  FIG. 20 is a cross-sectional view showing a state in which the soil filling net used in the cultivation system according to Embodiment 1 of the present invention is filled with soil, and the soil filling net is housed in the assembly-type planter when viewed from the front ( It is the BB sectional drawing of FIG. FIG. 21: is sectional drawing which shows the state which filled the soil inside the soil filling net | network used with the cultivation system which concerns on Embodiment 1 of this invention, and accommodated the soil filling net | network in the assembly-type planter from the upper surface side. FIG. 18 is a cross-sectional view taken along the line CC in FIG. When the protective bag 220 is extracted from the assembly type planter as described above, as shown in FIGS. 20 and 21, the outer peripheral surface of the soil filling net 210 inside the assembly type planter is formed by the protrusions 19 on the side walls 10 and 10A. It abuts against the tip and is regulated by the protrusions 19 to be prevented from abutting against the inner surface of the flat plate portions 11 and 11A of the side walls 10 and 10A (the inner surface of the thin portions 12 and 12A between the ribs 13 and 13A). The Of course, since the soil filling net 210 is made of a flexible material, a part (particularly a part corresponding to the gap between the protrusions 19) bulges due to the weight of the soil M, and a part of the flat part 11 of the side walls 10 and 10A. , 11A, but the ratio is small, and as a whole, a sufficient volume is provided between the inner surface of the flat plate portions 11, 11A of the side walls 10, 10A and the outer peripheral surface of the soil filling net 210. The internal space S is formed. This internal space S has a substantially long groove shape communicating in the vertical direction of the assembly type planter, functions as an air supply space (air supply passage) S to the soil M in the soil filling net 210, and is planted in the soil M Promotes the supply of air to the roots of the plant, and promotes the growth of the plant itself by promoting the growth of the roots. Furthermore, the internal space S forms a drainage path for excess water discharged from the soil M in the soil filling net 210 to the outside of the soil filling net 210. Therefore, the excess water discharged from the soil M in the soil filling net 210 to the outside of the soil filling net 210 can be stored inside without using the corner cover 51 as used in the assembly type planter according to the first example. By the space S, it can be guided downward inside the assembly type planter and drained to the outside through a drain hole or the like of the bottom wall 40, and leakage from the meshing surfaces of the connecting pieces 17, 18 can be prevented.

  FIG. 22 shows a garden filling container used in the cultivation system according to Embodiment 2 of the present invention placed on the bottom wall of the assembly-type planter so as to cover the drainage hole, and the soil filling net filled with the soil inside is attached to the soil filling net. It is sectional drawing which shows the state accommodated in the assembly-type planter seeing from the front side. As shown in FIG. 22, in the cultivation system according to Embodiment 2 of the present invention, the garden container floor 310 is placed on the bottom wall 40 of the assembly-type planter so as to cover the drainage hole. As the garden container bottom 310, for example, one having a size large enough to surround and cover each drainage hole on the bottom wall 40 of the assembly-type planter (for example, a hollow salt cone-shaped net), an assembly A large-sized one that surrounds and covers the entire drainage holes (for example, two drainage holes shown in FIG. 10) of the bottom wall 40 of the type planter can be used. Specifically, the large garden container base 310 is, for example, in the shape of a hollow substantially triangular prism having an opening at the lower end, and the opening at the lower end is disposed opposite to the drain hole portion of the bottom wall 40 to be mounted on the bottom wall 40. Can be placed. Further, the large garden container floor 310 may be integrally formed in such a three-dimensional hollow shape, but may be configured to be assembled by folding a flat plate shape into such a three-dimensional hollow shape. it can. That is, in the case of the assembly type, the garden container floor 310 is arranged on the bottom wall so as to surround the drainage hole (drainage hole) of the bottom wall 40 of the garden container of the assembly type planter. A pair of trapezoidal flat plate portions having the same shape of an elongated isosceles trapezoidal shape are integrally joined to each other so that they can be bent at the top and bottom, and a number of drain holes are formed through each of the trapezoidal flat plate portions. Yes. Further, in a total of two pairs of opposite sides on both sides of the bottom of the pair of trapezoidal flat plate portions, the opposite side for joining, which is one of the two opposite sides on each side, A triangular flat plate portion having an isosceles triangle shape having a pair of equal sides having the same length as the opposite side is integrally joined so as to be foldable at a joining equilateral side that is one of the pair of equilateral sides. A large number of drain holes are formed through each triangular flat plate portion. Furthermore, the locking equilateral sides that are opposite to the joining equilateral sides of the respective triangular plate portions are opposed to the engaging equilateral sides of the triangular plate portions and are adjacent to the joining opposite sides of the trapezoidal plate portions. Locking portions that can be locked with each other are integrally formed with the opposite sides for locking, which are opposite sides. The pair of trapezoidal flat plate portions are bent so as to approach each other, the pair of triangular flat plate portions are bent so as to approach the trapezoidal flat plate portion, and the locking portion of the triangular plate-like flat plate portion is bent to the trapezoidal flat plate. The trapezoidal flat plate portion and the triangular flat plate portion are inclined by symmetrically inclining both bottom surfaces, and below the pair of trapezoidal flat plate portions. It can be assembled into a hollow substantially triangular prism that forms a rectangular opening between the bottom and the bottom of the pair of triangular flat plate portions. Furthermore, the dimensions of the trapezoidal flat plate portion and the triangular flat plate portion are set so that the opening at the time of assembly completely surrounds the outside of the drain hole of the bottom wall of the garden container.

  According to the cultivation system which concerns on Embodiment 2, in addition to being able to form the said internal space S between the outer peripheral surface (side surface) of the soil filling net | network 210 with the protrusion 19 of an assembly-type planter, for gardening containers Also with the floor 310, an internal space having a predetermined volume can be formed on a part of the bottom surface (lower surface) of the soil filling net 210 (the drain hole corresponding portion of the bottom wall 40). Therefore, in addition to the air supply from the side of the soil filling net 210, the air supply from the lower surface actively supplies the outside air to the roots of the plants in the soil M, thereby further promoting the growth of the roots and the plants themselves. it can. By the way, in addition to arranging the gardening floor covering to cover the drainage hole of the bottom wall of the assembly type planter, the gardening flooring is integrally formed on the bottom wall, and the opening at the lower end of the gardening flooring is used as the drainage hole. You can also

  Here, the soil filling container of the present invention is not limited to the above soil filling net 220, as long as it can be filled with a predetermined type of soil and the excess water of the soil filled therein can be drained freely. Can be used. For example, as a soil filling container, a container made of an arbitrary material having a container shape having a large number of small holes having a hole diameter that prevents the soil from flowing out can be used besides the one on the net. In this case, for example, the soil filling container is in the shape of a synthetic resin container having a large number of small holes having a hole diameter that prevents the soil from flowing out. Such a container may be a flexible plastic sheet flexible container or a plastic rigid container. Furthermore, this soil filling container can also be configured such that a hook portion is integrally formed at the upper end portion, and is hooked and held by a predetermined frame. In this case, for example, the soil filling container can be supported by suspending the upper end of the gardening container from the upper end of the gardening container in a state where the entire gardening container such as the assembly type planter is accommodated. In the lower support state, an internal space is formed between the inner surface of the garden container and the outer surface of the soil-filled container filled with the soil, and external air can be freely supplied to the soil in the soil-filled container by the internal space. The surplus water of the soil in the soil filling container can be drained to the outside of the gardening container by the internal space. Specifically, for example, a cylindrical soil filling container having a circular opening (smaller than the gardening container) having a circular opening at the upper end of a cylindrical gardening container (such as a flower pot) having a circular opening at the upper end. The upper end is hooked, the same soil filling container is accommodated inside the gardening container, and an internal space for introducing outside air and draining is formed between the outer surface of the soil filling container filled with the soil and the inner surface of the gardening container. be able to. The upper end of the soil filling container is, for example, a circular hard ring attached to the upper end of a cylindrical soil filling container having a circular opening at the upper end and a closed lower end. The hard ring can be hooked on the upper end surface of the gardening container so as to have the same diameter as the circular upper end surface of the container. Alternatively, by making the outer shape of the circular hard ring the same as the inner diameter of the upper end opening of the garden container, and tightly fitting the outer peripheral surface of the hard ring to the inner peripheral surface of the upper end opening of the garden container, through the hard ring The soil filling container can be suspended and supported by the garden container. In addition, the present invention includes a frame body that is capable of hanging and supporting a large number of soil filling containers by hanging the upper end of the soil filling container, and supports the plurality of soil filling containers to be suspended from the frame body. It can also be embodied in a mass production type cultivation system (cultivating system for traders) in which a filling container is filled with a predetermined soil and plants corresponding to the soil in the soil filling container are cultivated collectively.

  Further, the present invention provides a design portion having a predetermined design on the upper end side of the soil filling container, and when the soil filling container is accommodated in the horticultural container in a state in which the predetermined soil is filled, the design portion is the upper end of the gardening container. A design corresponding to the design of the plant cultivated on the soil may be applied to the design portion. For example, select the color, pattern, material, etc. of the design part according to the color and pattern of the plant, the color of the leaves, the season and time (spring / summer / autumn / winter, Christmas, New Year), etc., and design the design part. Can be added. That is, the soil filling container such as the soil filling net 210 can exhibit design functions such as design and fashion, and thereby function as an object. For example, an exposed part that is exposed to the outside from the upper end of a gardening container such as an assembly-type planter is provided, and the exposed part is given a design such as a frill shape or a flare shape, or a predetermined color scheme, pattern, or texture is given to the exposed part Moreover, the function as seasonal goods, such as Christmas, can also be exhibited by giving material etc. suitably. Further, the soil filling net 210 of the above embodiment can be arbitrarily deformed into a desired shape by the net portion 211 which is a flexible material, but the soil filling container of the present invention is made of hard plastic as described above, etc. A certain degree of shape retention may be imparted. In any case, when the soil filling container is housed and used in the assembly type planter, an internal space is formed between the ridges 19 and the internal space functions as a drainage passage or an outside air introduction passage. Furthermore, the present invention also provides that the protective bag 220 can be placed in the garden container such as the assembly type planter without removing (removing) the protective bag 220 after the soil filling net 210 is accommodated together with the soil in the garden container such as the assembly type planter. The plant may be cultivated on the soil of the soil filling net 210 while being held in the soil. In this case, a large number of small holes are formed in the outer peripheral surface of the protective bag 220 to ensure air circulation from the internal space, and a large number of small holes are also formed in the bottom surface to drain excess water from the soil. Secure.

  Further, the present invention provides a predetermined portion on the upper end side of the soil filling container as a covering portion on the net, and when the soil filling container in which the covering portion is filled with the soil is accommodated in the garden container, the upper end of the garden container The surface of the soil can be completely covered except for the exposed portion of the plant planted in the soil of the soil filling container by the same covering portion so as to protrude outward from the opening of the soil covering, It is also possible to arrange the exposed portion of the plant on the top and to reduce the size of the covering by opening the covering portion with a fastening means such as a string. Alternatively, as shown in FIG. 15, the soil filling net 210 may be housed in a garden container such as an assembly planter with the fastening string 214 being squeezed and the upper end opening closed. In this case, the plant planted in the soil is exposed from a narrow open portion of the upper end opening of the soil filling container. In this way, most of the surface of the soil can be covered with the net part 211 except for the exposed portion of the plant (stem, stem, etc.), and pests such as slugs invade the soil from the top surface of the soil, Problems such as damage to the roots can be prevented. Further, in this state, a flare-like standing portion may be fixed to the outer peripheral side from the upper end opening (with the mouth narrowed) of the soil filling net 210. For example, as such a standing portion, a small lattice-like (fine mesh-like) color net (colored net) can be used to improve the design. Thus, by providing the standing portion on the outer peripheral side from the upper end opening (with the mouth narrowed) of the soil filling net 210, it is possible to more reliably prevent the invasion of pests such as slugs. In this case, pest repelling can be reliably performed by disposing the repellent only on the soil exposed surface inside the top opening of the soil filling net 210 (with the mouth narrowed). In any of the above cases, fertilization and watering can be performed on the soil through the net part 211 and the net part inside the standing part.

  In the present invention, the management tag represents an attribute of the soil to be filled in the soil filling container, and is associated with the soil filling container filled with the soil in a one-to-one relationship, and the soil filling container filled with the soil. As long as it manages, it can implement in arbitrary aspects. For example, the management tag is not only fixed to the fastening string 214 exposed from the reinforcement portion 212 of the soil filling net 210 as in the above embodiment, but also to the reinforcement portion 212 or to the net portion 211. can do. The management tag is not fixed to the soil filling container itself, but can be connected to the soil filling container in a detachable manner by a connecting means such as a detachable string or the position separated from the soil filling container, for example, the soil filling container Can be separably attached to a gardening container that accommodates the container. However, since the management tag represents the attribute of the soil filled in the soil filling container, it is most preferable that the management tag is fixed to the soil filling container itself, but it is attached at least in any location associated with the soil filling container. It is preferable that visual confirmation is possible from the outside. On the other hand, the management tag displays the attributes of the soil filled in the soil filling container (such as soil type, chemical composition, type of plant that can be grown, etc.), for example, to apply the cultivation system of the present invention to a home garden. In this case, an amateur user can easily perform continuous cropping of vegetables and the like. Specifically, for example, it is difficult to continuously use the soil after harvesting vegetables for vegetable cultivation, and it is necessary to restore the soil by leaving it for a certain period of time and exposing it to sunlight. Therefore, the soil filling container once used (cultivated vegetables) is taken out from the gardening container through the handle and stored in an appropriate place such as outdoors. Then, a new soil filling container filled with another soil is accommodated in the horticultural container, and vegetables are newly cultivated. Moreover, the restored soil can be newly used for vegetable cultivation by accommodating the soil-filled container in the gardening container again. In this way, the rotation of the soil through the soil filling container can be performed very easily. Therefore, the cultivation system according to the present invention can consistently and continuously manage the soil itself to be filled in the soil filling container such as the soil filling net 210 from the production stage to the use stage by the user, such as traceability. In addition to being able to demonstrate its function, it is also possible to indicate the type of plant to be cultivated, etc. by attaching a label such as “for soil” and “for soil” to the management tag for the soil in the soil filling container. It is possible to manage a series of processes from the stage of making soil on the producer side to housing the soil filling container in a horticultural container such as a planter and using it for cultivation on the user side. Can be That is, in order to perform cultivation using the soil filling net 210 and the protective bag 220 configured as described above, first, the soil M is filled and a desired seedling is grown. At this time, even if it is an amateur, it can be easily cultivated by selecting seeds and seedlings in advance from selection of the soil, and planting and raising seedlings and the like corresponding to the predetermined soil. In addition, in the cultivation of vegetables, it is necessary to rest the soil and reinforce the nutrients after one period has passed. In this case, after removing the entire net and storing it for a certain period of time, the recovered soil is again Use for cultivation. In this way, the land can be easily reused. At this time, the soil can be recovered at an early stage by applying a fertilizer made from household garbage or applying a commercially available fertilizer. In any case, since the soil is managed in units of soil filling containers, even those who are amateurs can perform the work very easily, and at this time, the necessary information is easily obtained by the management tag. Can definitely grow plants. The management tag can also be an IC tag. In this case, more information is stored in the IC tag and displayed to the user by a predetermined computer device, or automatically without being conscious of the user. It is also possible to perform various types of management using IC tags.

  By the way, the mesh roughness of the net portion 211 of the soil filling net 210 is set according to the type and particle size of the soil M to be filled therein, so that the soil M filled inside does not flow out or leak to the outside. Determine the mesh roughness. The material of the net part 211 can be formed into a net shape by knitting natural fibers, synthetic resin fibers, etc., or the synthetic resin can be directly formed into a net shape. However, in order to facilitate disposal after the lapse of the necessary period (expected usage period), it can also be formed into a net shape with a biodegradable resin.

  In addition to forming a quadrangular box with four side walls, the assembly-type planter is connected to a triangular box with three side walls, or a polygonal box such as a pentagonal box with five or more side walls. Can be connected to each other. Alternatively, the 10 side walls can be connected in a star shape. That is, the assembly-type planter of the present invention has three or more flat plate-like side walls that can be connected and separated from each other at the left and right side edges, and the three or more side walls are connected to form a cylindrical body. A bottom wall placed on the bottom of the cylindrical body, and a connecting rod for maintaining the connection between the connected side walls, and a plurality of connecting pieces at the left end and the right end of each side wall, It is integrally formed alternately so as to be staggered at the same arrangement interval, and the connecting pieces on the adjacent side walls are engaged with each other to be connected to each other, and the insertion hole is formed through the connecting piece in the axial direction. When the connecting pieces of the side walls that are engaged with each other are connected to each other, the insertion holes of the connecting pieces that are engaged with each other are communicated in a straight line with the same non-circular cross-sectional shape, and the connecting rod is a cross-sectional shape of the insertion hole. The connecting rods mesh with each other as the same non-circular cross-sectional shape It was by mounting the insertion hole of the coupling piece, to the extent that so as to prevent relative movement and relative rotation between the side walls and the connecting by the connecting rod may be of any configuration. Moreover, although the said side wall, a connecting rod, and a bottom wall can each be manufactured easily and cheaply by resin molding techniques, such as injection shaping, it can also manufacture using materials other than resin. Further, in FIG. 2, the support piece 21 protrudes from the flat plate portion 11 with a protruding amount smaller than the protruding amount of the connecting pieces 17 and 18 from the flat plate portion 11, but when assembling the four side walls 10 and 10A, As long as the adjacent support pieces 21 do not interfere with each other, all or at least a part of the support pieces 21 has a protruding amount equivalent to the protruding amount from the flat plate part 11 of the connecting pieces 17, 18, or Further, it may project from the flat plate portion 11 with a larger projecting amount. Note that the lengths of the pair of front and rear side walls 10 and the pair of left and right side walls may be the same without changing the length. For example, an assembly-type planter can be configured using four side walls 10 having the same configuration. In this case, the external shape of the assembly-type planter is a planar square shape. Moreover, it is preferable to give arbitrary design property, such as making the thin part 12 and 12A of the side walls 10 and 10A into the concave surface shape of predetermined curvature (R) besides making it into a flat surface. Further, the protrusion 19 may be provided only in a part without being provided over the entire length of the side walls 10 and 10A. In this case as well, an internal space similar to the above is formed and the intended function is exhibited. In addition to extending in the vertical direction, the protrusion 19 may be formed so as to extend in the oblique direction of the side walls 10 and 10A, or may be curved, or may have a different shape such as a bent shape or a jagged shape. Good. Furthermore, in the present invention, it is preferable to select the soil so that the soil filled in the soil filling container is as light as possible.

FIG. 1 is a perspective view showing an assembled state of an assembly-type planter as a horticultural container used in the cultivation system according to Embodiment 1 of the present invention. FIG. 2: is a figure which decomposes | disassembles and shows the structural member of the assembly-type planter used with the cultivation system which concerns on Embodiment 1 of this invention, (a) is the front view of a connecting rod, and the front view of a side wall in order from the left ( (Outer side view), Rear view of the side wall (inner side view), (b) is a top view of the side wall (viewed from the upper end side) and a bottom view of the side wall (viewed from the lower end side) ) Respectively. FIG. 3 is a front view for explaining the connection process between the side walls during assembly of the assembly-type planter used in the cultivation system according to Embodiment 1 of the present invention. FIG. 4 is a perspective view (corresponding to FIG. 3) for explaining a connection process between the side walls during assembly of the assembly-type planter used in the cultivation system according to Embodiment 1 of the present invention. FIG. 5 is a perspective view for explaining the insertion process of the connecting rod after connecting the four side walls during assembly of the assembly type planter used in the cultivation system according to Embodiment 1 of the present invention. FIG. 6 shows the assembly of the assembling-type planter used in the cultivation system according to Embodiment 1 of the present invention. After the four side walls are connected and fixed by the connecting rods in FIG. It is a perspective view which shows the process to perform. FIG. 7: is a top view (figure seen from the upper surface side) which shows the assembly state of the assembly-type planter used with the cultivation system which concerns on Embodiment 1 of this invention. 8 is a cross-sectional view taken along line AA in FIG. FIG. 9 is a perspective view showing a first alternative assembly type planter (with the connecting rod and corner cover removed) used in the cultivation system according to Embodiment 1 of the present invention. FIG. 10: is a bottom view (figure which looked at the assembly-type planter from the lower surface side) which shows the 1st example of the bottom wall of the assembly-type planter used with the cultivation system which concerns on Embodiment 1 of this invention. FIG. 11: is a bottom view (figure which looked at the assembly-type planter from the lower surface side) which shows the 2nd example of the bottom wall of the assembly-type planter used with the cultivation system which concerns on Embodiment 1 of this invention. FIG. 12 is a perspective view showing a second alternative assembly type planter used in the cultivation system according to Embodiment 1 of the present invention. FIG. 13: is sectional drawing which shows the state which piled up the assembly type planter of the 2nd another example used with the cultivation system which concerns on Embodiment 1 of this invention. FIG. 14 is a perspective view showing a soil filling net as a soil filling container used in the cultivation system according to Embodiment 1 of the present invention. FIG. 15 is a perspective view showing a state (state during transportation) in which the soil is filled into the soil filling net used in the cultivation system according to Embodiment 1 of the present invention and the upper end opening of the soil filling net is narrowed. . FIG. 16: is a perspective view which shows the state which filled the soil inside the soil filling net | network used with the cultivation system which concerns on Embodiment 1 of this invention, and accommodated the soil filling net | network in the protection bag as a protective container. . FIG. 17: is a perspective view which shows the state which filled the soil inside the soil filling net | network used with the cultivation system which concerns on Embodiment 1 of this invention, and accommodated the soil filling net | network in the assembly type planter. FIG. 18 is a bottom view showing an example of a break line provided on the bottom surface of the protective bag used in the cultivation system according to Embodiment 1 of the present invention. FIG. 19 shows a process in which the soil filling net used in the cultivation system according to Embodiment 1 of the present invention is filled with the soil, and the soil filling net is accommodated in the assembly-type planter. Sectional drawing which shows the state accommodated in the assembly-type planter in the state which accommodated the filling net in the protection bag, seeing from the front side, (b) is the said protection bag fractured | ruptured by the broken line of a bottom face, and extracted from an assembly-type planter It is sectional drawing which shows a state seeing from the front side. FIG. 20 is a cross-sectional view showing a state in which the soil filling net used in the cultivation system according to Embodiment 1 of the present invention is filled with soil, and the soil filling net is housed in the assembly-type planter when viewed from the front ( It is the BB sectional drawing of FIG. FIG. 21: is sectional drawing which shows the state which filled the soil inside the soil filling net | network used with the cultivation system which concerns on Embodiment 1 of this invention, and accommodated the soil filling net | network in the assembly-type planter from the upper surface side. FIG. 18 is a cross-sectional view taken along the line CC in FIG. FIG. 22 shows a garden filling container used in the cultivation system according to Embodiment 2 of the present invention placed on the bottom wall of the assembly-type planter so as to cover the drainage hole, and the soil filling net filled with the soil inside It is sectional drawing which shows the state accommodated in the assembly-type planter seeing from the front side.

Explanation of symbols

10, 10A: side wall, 17, 18: connecting piece, 19: protrusion, 31: connecting rod 110, 110A: connecting piece, 119: protrusion, 131: connecting rod 210: soil filling net (land filling container), 211 : Net part, 212: Reinforcement part 214: Fastening string (fastening means), 215: Management tag, M: Soil, S: Internal space

Claims (14)

  A soil filling container that can be filled with a predetermined type of soil and that can be used to drain surplus water of the soil filled therein, and a management tag that represents an attribute of the soil to be filled in the soil filling container. The management tag is associated with the filled soil filling container in a one-to-one relationship, the soil filling container filled with the soil is managed by the management tag, and the soil is filled together with the soil filling container in the gardening container. A cultivation system characterized in that the plant is cultivated with the soil filled in the soil filling container.   Further, the horticultural container for storing the soil-filled container filled with the soil has a ridge on the inner surface, and when the soil-filled container filled with the soil is stored in the horticultural container, An internal space is formed between the inner surface of the gardening container and the outer surface of the soil filling container filled with the soil, and the internal space allows free supply of outside air to the soil in the soil filling container, and the internal 2. The cultivation system according to claim 1, wherein surplus water of the soil in the soil filling container can be drained to the outside of the gardening container by a space.   The cultivation system according to claim 1, wherein the management tag is fixed to the soil filling container.   2. The cultivation system according to claim 1, wherein the soil filling container has a container shape having a large number of small holes having a hole diameter for preventing the soil from flowing out.   The soil filling container includes a mesh-roughened net portion that prevents the soil from flowing out, a reinforcing portion that reinforces an upper end opening portion of the net portion, and a fastening means that can freely fasten the upper end opening of the net portion. The cultivation system according to claim 4, comprising a soil filling net.   5. The cultivation system according to claim 4, wherein the soil filling container has a synthetic resin container shape having a large number of small holes having a hole diameter for preventing the soil from flowing out.   The gardening container has three or more flat side walls that are connected and separated from each other at the left and right side edges, and a bottom portion of the cylindrical body when the three or more side walls are connected to form a cylindrical body. An assembly-type planter having a bottom wall placed on the side wall and a connecting rod for maintaining the connection between the connected side walls. The assembly-type planter has a plurality of connecting pieces at the left end and the right end of each side wall. It is integrally formed alternately so as to be staggered at the same arrangement interval as its height dimension, and the connecting pieces on the adjacent side walls are engaged with each other and connected, and further, an insertion hole is formed in the axial direction of the connecting piece. When the connecting pieces of the adjacent side walls are formed so as to penetrate each other and are connected to each other, the insertion holes of the connecting pieces engaged with each other are connected in a straight line with the same non-circular cross-sectional shape, and the connecting rod is inserted into the insertion piece. The non-circular cross-sectional shape is the same as the cross-sectional shape of the hole. The connecting rod is installed in an insertion hole of the connecting piece meshed with each other, thereby preventing relative movement and relative rotation between the side walls connected by the connecting rod. 2 cultivation system.   The assembly type planter as the gardening container has four side walls having the same structure as the side walls, and the four side walls are connected to each other by engaging the connecting pieces of the adjacent side walls into a square box shape. The cultivation system according to claim 7, wherein the cultivation system is configured to be assembled, and is integrally formed on the inner side surface of each side wall so as to extend in the vertical direction.   The soil-filled container is supported in a state in which the garden container is substantially entirely accommodated, with its upper end suspended from the garden container and supported by the garden container. An internal space is formed between the inner surface of the container and the outer surface of the soil-filled container filled with the soil, and the internal space allows free supply of outside air to the soil in the soil-filled container. The cultivation system according to claim 1, wherein surplus water of the soil in the soil filling container can be drained to the outside of the gardening container.   The predetermined portion on the upper end side of the soil filling container is a design portion that is exposed to the outside from the opening at the upper end of the gardening container when the soil filling container filled with the soil is accommodated in the gardening container, and the design portion includes The cultivation system according to claim 1, wherein a design corresponding to a design of a plant to be cultivated on the soil is applied.   The predetermined portion on the upper end side of the soil filling container projects outside from the opening at the upper end of the gardening container when the soil filling container filled with the soil is accommodated in the gardening container, and is planted in the soil of the soil filling container The surface of the soil except for the exposed part of the plant is made into a net-like covering part that can be completely covered, the exposed part of the plant is arranged in the opening of the covering part, and the opening of the covering part is fastened The cultivation system according to claim 1, wherein the cultivation system is reduced by being reduced.   The inside of a predetermined type of soil can be filled freely, and the surplus water of the soil filled inside can be drained and can be drained, and can be stored inside the gardening container in the state filled with the soil. A soil-filling container for the cultivation system.   A top of the soil filling container according to claim 12 is hung, and a frame is provided that can freely support a large number of soil filling containers, and a number of soil filling containers are suspended and supported on the frame, and each soil filling is also provided. A cultivation system in which a container is filled with a predetermined soil, and plants corresponding to the soil in the soil filling container are cultivated in a lump. When three or more flat plate-like side walls that can be connected and separated from each other at the left and right edges and the three or more side walls are connected to form a cylindrical body, it is placed on the bottom of the cylindrical body. A bottom wall and a connecting rod for maintaining the connection between the connected side walls;
A plurality of connecting pieces are alternately formed integrally with the left end and the right end of each side wall so as to be staggered at the same arrangement interval as the height dimension, and the connecting pieces on adjacent side walls are engaged with each other to be connected. In addition, the insertion holes of the connecting pieces are formed in the axial direction of the connecting pieces, and the connecting holes of the connecting pieces engaged with each other when the connecting pieces on the adjacent side walls are connected to each other are connected to each other. By connecting the connecting rods to the insertion holes of the connecting pieces meshed with each other, the connecting rods having the same non-circular sectional shape as the sectional shape of the insertion holes, An assembly-type planter for a cultivation system, wherein relative movement and relative rotation between the connected side walls are prevented by the connecting rod.

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