JPH0524275Y2 - - Google Patents

Description

[Detailed Description of the Invention] (Field of Industrial Application) The present invention relates to a flower pot, and more specifically, to a flower pot for planting perennial bonsai, flowering trees, ornamental plants, etc. mainly for indoor ornamentation.

(Prior Art) Generally, a flowerpot is constructed such that a drainage hole is provided at the bottom of the flowerpot body which has a cylindrical shape with a bottom, and when the flowerpot body is irrigated, excess water is drained to the outside through the drainage hole. There is.

(Problem that the invention aims to solve) However, as the plants planted in the flower pot grow, their roots become fully embedded inside the flower pot body, which results in poor drainage during irrigation. If you give too much water, there will be excess moisture in the roots, which will impede ventilation to the roots, resulting in insufficient oxygen supply to the roots, which will cause root rot.
There were problems with plants dying or withering.

The purpose of this invention is to improve the drainage effect regardless of the level of root tension, prevent root rot caused by excessive water during irrigation, and improve ventilation to the roots. ,Moreover,
By filling the flower pot with water and keeping it in a submerged state, even when the soil is extremely dry, sufficient water can be supplied and the air in the soil can be exchanged well. The point is to provide flower pots.

(Means for solving the problem) However, the present invention has a bottomed cylindrical flower pot body 1
and a large number of through holes 31, and the flowerpot body 1
and a cavity 30 formed between the upper base 3 and the bottom wall 10 of the main body 1, and having a water suction pipe with a predetermined diameter or less, the cavity 3
The flower pot body 1 is a flower pot that uses a suction pump that can suck up water that accumulates in the water.
an insertion hole that vertically penetrates from the upper part of the main body 1 into the cavity 30 and has a size that allows the water suction pipe of the suction pump to be inserted therethrough, and that allows the water suction pipe to be opened in the cavity 30; A through hole 21 having a hollow cylindrical part 2 having a diameter of 2a, the cylindrical part 2 opening into the flower pot main body 1, and having a size that enables drainage of water to irrigate the flower pot main body 1 loaded with soil. It has a large number of.

(Function) With the above configuration, when watering into the flowerpot body 1,
Excess moisture accumulated in the root portion is quickly discharged from the through hole 21 of the hollow cylindrical part 2 into the cavity 30 through the interior of the cylindrical part 2, and unnecessary water accumulated in the cavity 30 is removed. By sucking up water with a suction pump through a water suction pipe and draining it to the outside, the drainage effect is enhanced even when the roots are tightly packed inside the flowerpot body 1, and the water accumulated in the empty space 30 is removed. It is possible to prevent the occurrence of root rot due to unnecessary water, and at the same time, after drainage, the through holes 21 are used to ventilate the roots, thereby preventing the occurrence of root rot. You can fill water up to the top of the main body 1 and keep it submerged, so even if the soil is extremely dry, water can be distributed evenly from the soil at the bottom of the flower pot to the soil at the top. This allows sufficient water to be supplied to the soil and roots, and
Even if water is supplied in this way, it can be quickly and easily drained by a suction pump via the water suction pipe after a certain period of time, so it will not have any negative impact on the roots, and the soil will be The air inside can be exchanged easily.

(Example) Fig. 1 shows a flower pot of the present invention, in which 1 is a cylindrical flower pot body with a bottom, and an upper base 3 having a large number of through holes 31 is provided at the lower part of the body 1. A cavity 30 is formed between the bottom 3 and the bottom wall 10 of the main body 1.

Legs 32 are provided at the lower part of the upper sole 3, and the outer periphery of the upper sole 3 has a substantially semicircular cross section.
A plurality of insertion holes 33 for the hollow cylindrical body 2, which will be described later, are formed, and a plurality of holding pieces 12, 12 for holding the upper part of the hollow cylindrical body 2, which will be described later, are provided on the inside upper part of the flower pot main body 1. ing.

In addition, a manual or electric suction pump P is used to suck up and discharge the water accumulated in the empty chamber 30, and the pump P includes a water suction pipe P ₁ of a predetermined diameter or less, that is, a flower pot body. A water suction pipe _P1 having a diameter considerably smaller than the inner diameter of the main body 1 is provided so as not to hinder the growth of roots within the main body 1.

2 extends vertically from the upper part of the main body 1 into the empty space 30, and connects to the suction pump P.
A hollow cylindrical body (hollow cylindrical part) having an insertion hole 2a that is sized to allow the water suction pipe P ₁ to be inserted therethrough and that allows the water suction pipe P ₁ to be opened in the cavity 30.
A large number of through holes 21 are formed on the outer periphery of the cylindrical body 2 and have a size that opens into the flowerpot body 1 and allows drainage of water to be used for watering the flowerpot body 1 loaded with soil. An opening 22 is formed in the lower end side wall of the tubular body 2, and the hollow tubular body 2 is connected to the flowerpot by the holding piece 12 of the flowerpot body 1 and the insertion hole 33 of the upper base 3. It is configured to be held along the inner wall of the main body 1.

Further, on the upper base 3 of the flowerpot body 1, coarse stones are spread as soil to improve drainage.
Nutrient soil is placed on top of these rough stones, and plants are planted in the nutrient soil area.

Thus, during irrigation, excess moisture accumulated in the roots quickly flows from the through hole 21 of the hollow cylindrical part 2 into the cavity 30 through the inside of the cylindrical part 2.
When water accumulates in the empty space 30, insert the water suction pipe _P1 of the manual or electric suction pump P into the insertion hole 2a of the cylindrical body 2, and insert the tip of the water suction pipe _P1 into the empty space. 30, and the suction pump P sucks up the water accumulated in the cavity 30 and drains it to the outside, so that the inside of the cylindrical body 2 and the interior of the cavity 30 are separated. It is hollow, and has through holes 21 in the cylindrical body 2 as well as through holes 31 in the upper base 3.
This also allows for sufficient aeration to the roots, which allows for a sufficient supply of oxygen to the roots and prevents root rot.

On the other hand, in the present invention, a hollow chamber 30 having no drainage hole is formed in the bottom wall 10 of the flowerpot body 1, and a suction pump is used to remove the water from the flowerpot body 1 by using the insertion hole 2a of the hollow cylindrical body 2. The water accumulated in the bottom cavity 30 of the flower pot can be freely drained, so it is possible to fill the flower pot body 1 with water to the top and maintain the submerged state, even when the soil is extremely dry. , it is possible to distribute water evenly from the soil at the bottom of the flower pot to the soil at the top, and to supply sufficient water to the soil and roots.Also, even when water is supplied in this way, the suction pump is used after a predetermined period of time. Since the soil can be drained, it does not have any negative impact on the roots, and the air in the soil can be easily exchanged through the above-mentioned water absorption and drainage operations.

When air is removed from the soil, water can be injected through the insertion hole 2a of the hollow cylindrical body 2, so water is gradually raised from the bottom of the flowerpot body 1 and supplied to the soil above. This allows the air to be removed in a short time and efficiently.

In addition, when using the suction pump P as described above, there is no need to carry the flowerpot outside or take it out to the balcony every time you water the flowerpot.
This eliminates the need for the heavy labor of carrying flower pots, and even if the flower pot is placed on the floor or desk, water will not leak onto the floor soil or desk surface.In addition, a saucer installed at the bottom of the flower pot to prevent water leakage can be used. can also be made unnecessary.

In addition, the liquid sucked up by the pump P can be stored in a storage tank and used again for irrigation, or as water for other flower pots, without letting the nutrients in the liquid escape.

In addition, when going out for a long period of time, after draining excess water from the flowerpot body 1, water or a nutrient solution is poured into the cavity 30 from the hollow cylindrical body 2 to the upper part of the cavity 30. While injecting water to the extent that a slight air layer is left, a water-absorbing material such as felt is inserted into the hollow cylindrical body 2 so that its lower part is immersed in the water or nutrient solution in the cavity 30. The water or nutrient solution is sucked up to the upper part of the water-absorbing material by capillary action, and as a result, the roots that have entered the hollow cylindrical body 2 through the through hole 21 of the hollow cylindrical body 2 are drawn up from the water-absorbing material. It is possible to absorb water and nutrient solution, so that it is not necessary to supply water or nutrient solution for a long time while water or nutrient solution is present in the cavity 30.

Although the hollow cylindrical body 2 is formed separately from the flowerpot body 1 in the above embodiments, the hollow cylindrical body 2 may be integrally formed with the flowerpot body 1.
Further, the shape of the hollow cylindrical body 2 and the shape of the through hole 21 are not limited at all, and for example, the hollow cylindrical body 2 may be formed into a cylindrical shape using a wire mesh.

(Effect of the invention) As described above, the present invention has a bottomed cylindrical flower pot body 1
and a large number of through holes 31, and the flowerpot body 1
and a cavity 30 formed between the upper base 3 and the bottom wall 10 of the main body 1, and having a water suction pipe with a predetermined diameter or less, the cavity 3
The flower pot body 1 is a flower pot that uses a suction pump that can suck up water that accumulates in the water.
an insertion hole that vertically penetrates from the upper part of the main body 1 into the cavity 30 and has a size that allows the water suction pipe of the suction pump to be inserted therethrough, and that allows the water suction pipe to be opened in the cavity 30; A through hole 21 having a hollow cylindrical part 2 having a diameter of 2a, the cylindrical part 2 opening into the flower pot main body 1, and having a size that enables drainage of water to irrigate the flower pot main body 1 loaded with soil. When watering the inside of the flower pot body 1, excess moisture accumulated in the roots is quickly transferred from the through hole 21 of the hollow cylindrical part 2 into the empty chamber 30 through the insertion hole 2a. The unnecessary water accumulated in the empty chamber 30 is sucked up by the suction pump through the water suction pipe and drained to the outside.
Even when the roots are tightly packed inside the flower pot body 1, the drainage effect can be improved and root rot caused by unnecessary water accumulated in the empty chamber 30 can be prevented. While being able to provide good ventilation to the roots, a cavity 30 having no drainage hole is formed in the bottom wall 10 of the flowerpot body 1, and the insertion hole 2a of the hollow cylindrical part 2 is utilized. Then, water accumulated in the bottom cavity 30 of the flowerpot body 1 can be arbitrarily sucked up by the suction pump through the water suction pipe and drained to the outside, so that water can be filled up to the top of the flowerpot body 1. Even when the soil is extremely dry, it can evenly distribute water from the soil at the bottom of the flower pot to the soil at the top, ensuring sufficient water to reach the soil and roots. Furthermore, even if water is supplied in this way, it can be quickly and easily drained by a suction pump via the water suction pipe, so it will not have a negative effect on the roots. Moreover, the air in the soil can be easily exchanged through the above-mentioned water supply and drainage operations.

Furthermore, when performing the air removal, water can be injected through the insertion hole 2a of the hollow cylindrical part 2, so water is gradually raised from the bottom of the flowerpot body 1 and supplied to the soil at the top. This allows the air to be removed in a short time and efficiently.

Moreover, when going out for a long period of time, water or nutrient solution is injected into the cavity 30 from the hollow cylindrical part 2 to the extent that a slight air layer is left in the upper part of the cavity 30. Using the insertion hole 2a of the hollow cylindrical portion 2, insert a water absorbent material such as felt into the insertion hole 2a, the lower part of which is immersed in the water or nutrient solution accumulated in the hollow chamber 30, and the upper part of which is a flower pot. If the water or nutrient solution is inserted so as to be positioned on the upper side, the water or nutrient solution in the cavity 30 will be sucked up to the upper part of the water-absorbing material by capillary action, and as a result, the Water and nutrient solution are supplied from the water-absorbing material to the soil and roots that come into contact with the water-absorbing material, and as a result, water and nutrient solution are not supplied for a long period of time while water and nutrient solution are present in the cavity 30. You don't have to give it.

[Brief explanation of drawings]

FIG. 1 is a partially omitted vertical sectional view showing an embodiment of the flower pot of the present invention, and FIG. 2 is a plan view of the upper base. 1...Flower pot body, 2...Hollow cylindrical body, 2a...
...Through hole, 21...Through hole, 3...Top bottom, 31...
Through hole.

Claims (1)

[Scope of utility model registration request] A cylindrical flowerpot body 1 with a bottom and a large number of through holes 31
It has an upper base 3 disposed at the lower part of the flowerpot body 1, and a cavity 30 formed between the upper base 3 and the bottom wall 10 of the body 1, and has a water absorption capacity of a predetermined diameter or less. The flowerpot is equipped with a suction pump that has a pipe and is capable of sucking up water accumulated in the empty space 30, and the flower pot body 1 is vertically penetrated from the upper part of the main body 1 into the empty space 30. and has a hollow cylindrical part 2 having an insertion hole 2a that is sized to allow a water suction pipe of the suction pump to be inserted therethrough and that allows the water suction pipe to be opened in the cavity 30; A flowerpot characterized in that a large number of through holes 21 are opened into the flowerpot body 1 and are sized to allow drainage of water for watering the flowerpot body 1 loaded with soil.