JP2014075985A - Plant container - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a plant container capable of sufficiently replacing air contained in potted soil.SOLUTION: A plant container has a container body 12 comprising a top part 11 which is open and a drain outlet 14 located at a bottom part 15, and a mesh plate 21 which divides the inside of the container body 12 into an upper potted soil chamber 22 and a lower air chamber 23. The mesh plate 21 forms a through-hole 24 for communicating between the potted soil chamber 22 and the air chamber 23. In addition, an opening/closing mechanism 30 operating in both open and closed states of the drain outlet 14 is installed on the outside of the container body 12 having the potted soil chamber 22 and the air chamber 23.

Description

  The present invention relates to a plant container used by planting a plant.

  When cultivating or displaying plants, plants are often planted in plant containers such as flower pots and planters (see Patent Document 1). A drain outlet is formed at the bottom of such a plant container, and excess water is discharged from the drain outlet when water is supplied to the soil in the plant container.

JP 2007-61104 A

  By the way, the purpose of the water supply operation for the plant container is not only to supply water to the soil but also to replace the air in the soil. However, as described in Patent Document 1, when a plant container in which a drain port is simply formed on the bottom is used, the supplied water immediately flows out from the drain port. It was difficult to fill the water with water, and it was difficult to sufficiently replace the air in the soil.

  Moreover, in the container for plants of patent document 1, although it has the structure which receives the water which flowed out from the drain outlet at the time of water supply operation | work with a saucer, in such a structure, the process of the water collected on the saucer is only required. In addition, it is possible that water overflows from the tray during water supply work. As described above, the water supply operation for the plant container often involves a complicated operation, and simplification of the water supply operation is desired.

  An object of the present invention is to sufficiently replace the air in the soil and to simplify the water supply work.

  The plant container according to the present invention is a plant container used by planting a plant, the container main body having an upper opening and a drain outlet in the lower part, and the container main body provided above the container main body. A partition member that is divided into a soil chamber and a lower air chamber and includes a communication hole that communicates the soil chamber and the air chamber, and is provided outside the soil chamber and the air chamber of the container body. And an open / close mechanism that operates in a closed state in which the drain port is closed and an open state in which the drain port is opened.

  According to the present invention, since the open / close mechanism that operates in the closed state that closes the drain port and the open state that opens the drain port is provided, the water is discharged from the soil chamber after the soil chamber is filled with water. It is possible to replace the air in the soil sufficiently. In addition, since an open / close mechanism that operates in a closed state that closes the drain port and an open state that opens the drain port is provided, water does not immediately flow out of the drain port during water supply work, simplifying the water supply work It becomes possible to plan. Moreover, since the opening / closing mechanism is provided outside the soil chamber and the air chamber, it is possible to prevent the soil from biting into the opening / closing mechanism and entanglement of plants, and to prevent malfunction of the opening / closing mechanism. Become.

It is a perspective view which shows the use condition of the container for plants which is one embodiment of this invention. (a) is a perspective view which shows the container for plants from the upper part, (b) is a perspective view which shows the container for plants from the lower part. It is a disassembled perspective view which shows the structure of the container for plants. (a) And (b) is sectional drawing which shows the structure of the container for plants along the AA line of Fig.2 (a). (a)-(c) is explanatory drawing which shows the process of the water supply operation | work with respect to the container for plants. It is a perspective view which shows the other use condition of the container for plants.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a perspective view showing a use state of a plant container 10 according to an embodiment of the present invention. 2A is a perspective view showing the plant container 10 from above, and FIG. 2B is a perspective view showing the plant container 10 from below. FIG. 3 is an exploded perspective view showing the structure of the plant container 10. 4 (a) and 4 (b) are cross-sectional views showing the structure of the plant container 10 along the line AA in FIG. 2 (a).

  As shown in FIG. 1, the plant container 10 is a container used by planting a plant P together with the soil S. As the soil S, for example, ceramics, pumice, perlite, gel culture soil, red jade soil, black soil, humus soil or the like is used depending on the type of plant P, the growth environment, and the like. As shown in FIGS. 2 to 4, the plant container 10 has a bottomed cylindrical container body 12 with an upper portion 11 opened. The container main body 12 has a cylindrical side wall part 13 and a bottom part (lower part) 15 in which a drain port 14 is formed. A convex portion 16 projecting radially inward is formed on the inner side of the side wall portion 13, and a rod hole 17 penetrating vertically is formed in the convex portion 16. The illustrated container body 12 has a cylindrical shape, but is not limited thereto. For example, the container body 12 may be formed in a cylindrical shape having a cross-sectional shape such as an ellipse or a polygon, and the side wall portion 13 of the container body 12 may be formed in a tapered shape.

  An annular step 20 is formed in the container body 12, and a mesh plate (partition member) 21 is installed on the step 20. Thus, by inserting the mesh plate 21 into the container body 12, the upper soil chamber 22 and the lower air chamber 23 are partitioned in the container body 12 with the mesh plate 21 as a boundary. A plurality of through holes (communication holes) 24 are formed in the mesh plate 21, and the soil chamber 22 and the air chamber 23 are in communication with each other through the through holes 24. The size of the through hole 24 of the mesh plate 21 is desirably set to a size that allows the water S to pass therethrough and blocks the soil S. The illustrated mesh plate 21 is manufactured by insert molding, and the mesh plate 21 includes a frame body 25 made of a plastic material and a metal plate 26 having a large number of through holes 24.

  The container body 12 is provided with an opening / closing mechanism 30 that operates in a closed state in which the drain port 14 is closed and an open state in which the drain port 14 is opened. The opening / closing mechanism 30 includes a push rod (rod member) 31 operated by a user and a leaf spring member (closing member) 32 that closes the drain port 14 from the outside. The push rod 31 includes a rod body 33 that is inserted into the rod hole 17 of the container body 12 from below, and a cap 34 that is detachably screwed to the end of the rod body 33 that protrudes upward from the rod hole 17. ing. Further, as shown in FIGS. 2B and 3, the leaf spring member 32 attached to the bottom portion 15 of the container body 12 includes a restraining portion 36 that engages with the claw portion 35 of the container body 12, and the drain port 14. A closing portion 38 provided with a packing 37 that closes the contact rod, and a contact portion 40 provided with a recess 39 with which the push rod 31 contacts. As described above, the lower end (one end) 31 a of the push rod 31 is in contact with the leaf spring member 32, while the upper end (other end) 31 b of the push rod 31 protrudes upward from the rod hole 17. Yes.

  Next, the operating state of the opening / closing mechanism 30 will be described. As shown in FIG. 4A, when the push rod 31 is not operated by the user, the packing 37 of the closing portion 38 is pushed upward by the spring force of the leaf spring member 32, and the packing 37 is connected to the drain port 14. It is in a state of being pressed against the end face. That is, when the push rod 31 is not operated, the opening / closing mechanism 30 operates in a closed state in which the drain port 14 is closed. On the other hand, when the upper end portion 31b of the push rod 31 is pushed down by the user, the contact portion 40 of the leaf spring member 32 is pushed down by the lower end portion 31a of the push rod 31 as shown by the white arrow in FIG. Thus, the packing 37 is separated from the end surface of the drain port 14. That is, when the push rod 31 is pushed down, the opening / closing mechanism 30 operates in an open state in which the drain port 14 is opened. As shown in FIG. 4B, a plurality of legs 41 are provided on the bottom 15 of the container main body 12 so as to extend downward from the pushed-down position of the leaf spring member 32.

  Next, the water supply operation for the plant container 10 will be described. FIGS. 5A to 5C are explanatory views showing a process of water supply work for the plant container 10. FIG. 5 (a) shows the state of the plant container 10 at normal times, FIG. 5 (b) shows the state of the plant container 10 during water supply, and FIG. 5 (c) shows the state during drainage. The state of the plant container 10 is shown. In FIGS. 5B and 5C, the supplied water is indicated by light ink.

  As shown in FIG. 5A, when planting the plant P in the plant container 10, the soil S is put together with the underground portion of the plant P into the soil chamber 22 above the mesh plate 21. . Here, although the mesh plate 21 is formed with a through hole 24 that allows the soil chamber 22 and the air chamber 23 to communicate with each other, the size of the through hole 24 is formed to be a size that blocks the soil S. For this reason, the air chamber 23 below the mesh plate 21 is not filled with the soil S, and the air chamber 23 is filled with air. It goes without saying that a small amount of the soil S may enter the air chamber 23 depending on the size of the through holes 24 formed in the mesh plate 21 and the size of the particles of the soil S used.

  Subsequently, as shown in FIG. 5 (b), when performing a water supply operation for pouring water into the plant container 10, the opening / closing mechanism 30 is held in a closed state to keep the drain port 14 closed, and the arrow X1 As shown, the water supply operation is performed on the soil chamber 22 of the container body 12. This water supply operation is continued until the soil surface is covered with water, that is, until the soil chamber 22 and the air chamber 23 are filled with water. After such a water supply operation is completed, a drainage operation for discharging excess water from the plant container 10 is performed. As shown in FIG.5 (c), when performing drainage work, as shown by arrow X2, pushrod 31 is pushed in by the user. As a result, the opening / closing mechanism 30 is switched to the open state and the drain port 14 is opened, so that excess water is discharged from the drain port 14 as indicated by an arrow X3. This drainage operation is continued until the drainage from the drainage port 14 is stopped, that is, until the water is sufficiently discharged from the soil chamber 22 and the air chamber 23.

  As described above, it is possible to discharge excess water after filling the soil chamber 22 with water by a simple operation of pushing the push rod 31 after water supply. Thereby, since appropriate water can be supplied to the soil and the air in the soil can be replaced, the growth environment of the plant P can be adjusted well. That is, as shown in FIG. 5B, by performing the water supply operation with the drain port 14 closed, it is possible to reliably submerge all the soil S accommodated in the soil chamber 22. Then, as shown in FIG. 5 (c), by opening the drain port 14 and lowering the water level of the soil chamber 22, new air can be introduced into the entire soil of the soil chamber 22 as indicated by the arrow X4. It becomes possible. And since the drain outlet 14 can be closed at the time of water supply operation | work, it becomes possible to suppress the amount of water required in order to submerge the whole soil. In addition, since the drain port 14 can be closed during the water supply operation, water does not immediately flow out of the drain port 14, and the water supply operation can be performed very easily. Furthermore, since the air chamber 23 is provided below the soil chamber 22, excessive moisture is not retained in the soil, and root decay of the plant P can be prevented.

  Further, since the opening / closing mechanism 30 is configured by the leaf spring member 32 and the push rod 31, the opening / closing mechanism 30 can be easily configured, and the manufacturing cost of the plant container 10 can be reduced. Furthermore, since the opening / closing mechanism 30 is provided outside the soil chamber 22 and the air chamber 23, it is possible to prevent biting of the soil S into the opening / closing mechanism 30 and the entanglement of the roots of the plant P with respect to the opening / closing mechanism 30. It becomes possible to prevent malfunction of the opening / closing mechanism 30. In addition, by providing the opening / closing mechanism 30 outside the soil chamber 22 and the air chamber 23, even if the opening / closing mechanism 30 breaks down, the plant P having a root in the soil chamber 22 is taken out. Therefore, the opening / closing mechanism 30 can be repaired.

  In addition, since the cap 34 is detachably provided on the rod body 33, by setting caps of various shapes and colors, the user can select and replace the desired cap, The merchantability of the container 10 can be increased. In the illustrated case, the rod body 33 and the cap 34 are screw-coupled, but the present invention is not limited to this, and the cap 34 can be attached to and detached from the rod body 33 by other structures such as fitting. You may make it provide in. In addition, since the leg portion 41 extending below the position where the leaf spring member 32 is pushed down is provided on the bottom portion 15 of the container body 12, the drainage operation can be easily performed while the plant container 10 is placed on the sink. It becomes possible. That is, even when the push rod 31 is pushed in while the plant container 10 is placed on a sink or the like, it is possible to avoid interference between the sink and the leaf spring member 32.

  It goes without saying that the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the invention. For example, in the case shown in FIG. 1, the plant container 10 is used while being exposed, but is not limited thereto. Here, FIG. 6 is a perspective view showing another use state of the plant container 10. As shown in FIG. 6, the plant container 10 may be housed in a decorative case 42 and used. Moreover, you may use the container 10 for plants accommodated in containers, such as a flowerpot, a coffee cup, and a vase.

  In addition, although the container main body 12, the rod main body 33, and the leaf | plate spring member 32 are formed using a plastic material (for example, polypropylene), it is not restricted to this, A container main body using glass material, a metal material, etc. 12 etc. may be formed. Moreover, although the packing 37 and the cap 34 are formed using an elastic material (for example, silicon rubber), it is not restricted to this, You may form the packing 37 etc. using another material. Further, the mesh plate 21 is formed by combining a metal material (for example, stainless steel) and a plastic material (for example, polypropylene). However, the mesh plate 21 is not limited to this, and the mesh plate 21 is formed using only the metal material. Alternatively, the mesh plate 21 may be formed using only a plastic material. Furthermore, the partition member described as the mesh plate 21 may be formed using a wire mesh or a non-woven fabric, or may be formed using a porous material such as ceramics.

DESCRIPTION OF SYMBOLS 10 ... Container for plants, 11 ... Upper part, 12 ... Container main body, 13 ... Side wall part, 14 ... Drain outlet, 15 ... Bottom part (lower part), 16 ... Convex part, 17 ... Rod hole, 20 ... Step part, 21 ... Mesh Plate (partition member), 22 ... Earth chamber, 23 ... Air chamber, 24 ... Through hole (communication hole), 25 ... Frame, 26 ... Metal plate, 30 ... Opening / closing mechanism, 31 ... Push rod (rod member), 31a ... lower end (one end), 31b ... upper end (other end), 32 ... leaf spring member (blocking member), 33 ... rod body, 34 ... cap, 35 ... claw part, 36 ... restraint part, 37 ... packing , 38 ... Blocking part, 39 ... Dimple, 40 ... Contact part, 41 ... Leg part, 42 ... Decorative case, S ... Soil, P ... Plant

Claims (4)

A plant container used for planting,
A container body that is open at the top and has a drain at the bottom;
A partition member provided in the container main body to partition the inside of the container main body into an upper soil chamber and a lower air chamber, and having a communication hole for communicating the soil chamber and the air chamber;
An opening / closing mechanism provided outside the soil chamber and the air chamber of the container body and operating in a closed state for closing the drainage port and an open state for opening the drainage port. Plant container. The plant container according to claim 1,
The plant container comprising: a closing member that closes the drainage port from the outside of the container body; and a rod member that presses the closing member to open the drainage port. The plant container according to claim 2,
The rod member is accommodated in a rod hole that vertically penetrates the container body,
One end of the rod member contacts the closing member, while the other end of the rod member protrudes upward from the rod hole. In the container for plants of Claim 2 or 3,
The plant container, wherein the closing member is a leaf spring member comprising a restraining portion restrained by the container body and a closing portion for closing the drain port.

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