JPH09205892A - Flowerpot and its water level controller - Google Patents

Abstract

PROBLEM TO BE SOLVED: To hold the moisture of compost nearly constant by automatically pouring water to the compost in the flowerpot without a hand or electric power. SOLUTION: This flowerpot 1 is equipped with a compost storage part 1a and a water storage tank part 1b which automatically feeds water to the compost storage part 1a and has its top made open. Then, an overflow opening part 1e which projects up cylindrically is formed on the bottom part of the compost storage part 1a to form a water reservoir part where the water from the water storage tank part 1b is reserved. Further, the water level controller 2 opens and closes the feed water path between the compost storage part 1a and water storage tank part 1b by making good use of the buoyancy of a float.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flowerpot (including a box-shaped one, that is, a planter) provided with a water storage tank and a water level adjuster used therein.

[0002]

2. Description of the Related Art Conventionally, as an automatic watering device for flower pots,
It is known to supply water for a time with a hose laid from a water supply.

[0003]

SUMMARY OF THE INVENTION The above automatic irrigation system has difficulty in supplying an appropriate amount of water corresponding to the weather (rainy weather, cold and warm) of the day, is likely to be too wet or too dry, and drives the system. It also requires electricity.

It is an object of the present invention to automatically irrigate the culture soil in a flowerpot and maintain the moistness of the culture soil substantially constant without requiring any manual labor or electric power.

[0005]

The flowerpot of the present invention has a culture soil accommodating portion 1a and a water storage tank portion 1b having an open upper portion for automatically supplying water to the culture soil accommodating portion 1a. .

In a plant pot having a culture soil storage portion 1a and a water storage tank portion 1b for automatically supplying water to the culture soil storage portion 1a, an overflow port protruding upward in a cylindrical shape at the bottom of the culture soil storage portion 1a. It is advisable to form the portion 1e to serve as a water reservoir 1f for accumulating water in the water tank portion 1b.

The water level controller 2 is adapted to open and close a water supply passage 2j in a flowerpot 1 having a culture soil accommodating portion 1a and a water storage tank portion 1b by utilizing the buoyancy of the float 2c.

[0008]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of a flower pot and a water level controller used therein according to the present invention will be described with reference to FIGS.

This flower pot 1 is generally equipped with a culture soil storage section 1a.
And a water tank portion 1b. Also, the water level controller 2
Is stored in the water storage tank portion 1b of the flower pot 1 in order to keep the water level of the culture soil storage portion 1a (water storage portion 1b) constant.

The flower pot 1 has a bottomed cylindrical shape, a box shape or the like, and the shape thereof is not particularly limited. The material may be any material, such as synthetic resin, ceramics, and metal, as long as water does not exude.

In the flower pot 1 shown in FIGS. 1 and 3, the outer wall 1c and the inner wall 1d are doubled, and the space between them serves as a water tank portion 1b. However, the water storage tank portion 1b does not necessarily have to be arranged so as to surround the culture soil accommodating portion 1a, and may be arranged on one side of the culture soil accommodating portion 1a. In short,
The culture soil accommodating portion 1a and the water storage tank portion 1b may be open above. By doing so, the structure of the water storage tank portion 1b can be simplified. Further, the shape of the flower pot can be freely determined, and when it is made of plastic, its molding is extremely easy. In addition, even if the material is opaque, the water level in the water tank portion 1b can be seen from above, so the timing of replenishing water will not be missed.

On the wall surface 1d below the culture soil container 1a,
A water inlet 1g leading to the water tank portion 1b is provided.

At the bottom of the culture soil accommodating portion 1a, there is provided an overflow port portion 1c projecting upward in a cylindrical shape. A portion below the position slightly lower than the upper end of the overflow port portion 1c becomes a water reservoir portion 1f in which water flowing out from the water storage tank portion 1b via the water level adjuster 2 is accumulated. The water level of the water reservoir 1f is determined by the position setting of the float 2c of the water level adjuster 2 described later. The overflow port 1e can be covered with a lid with packing. This is effective when the flowerpot is placed in a place where water should not be spilled, such as indoors. When the flower pot is placed outdoors, the lid may be removed because it may be rained and water may become excessive.

The water level adjuster 2 accommodates a float 2c, has a water inlet 2d and a water outlet 2e, and is a space which is a space separated by a partition 2f having an L-shaped hole. It is composed of a tubular portion 2b which communicates with the upper portion thereof and extends at least to the upper end position of the container 1 and which has a vent hole 2g in the upper portion.

The water inlet 2d and the water outlet 2e are provided with filters 2h and 2i which are in close contact with each other to prevent the infiltration of the culture soil. A hole 2j is formed at the bottom of the partition wall 2f, and an annular packing 2k such as rubber is attached to the hole 2j.

The float 2c is integrated with a sled 2l whose main part is conical, and there are two types depending on the difference in the relationship between the sled 2l and the packing 2k.

One is the float 2c shown in FIGS.
Is provided on the upper side of the partition wall 2f, and the sled 2l is attached to the lower surface thereof. As shown in FIG. 7, the snout 2l has a lower end protruding below the hole 2j of the partition wall 2f. The outer diameter of the lowermost end of the snail 2l is larger than the inner diameter of the packing 2k, and gradually decreases as it goes upward through a portion equal to the inner diameter of the packing 2k. However, the integrated portion with the float 2c has a constant diameter.

The other is that the float 2c shown in FIGS. 8 to 11 is provided below the partition wall 2f, and the slant 2l is provided on the upper surface thereof.
Is installed. As shown in FIG. 11, the upper end of the slant 2l is applied to the hole 2j of the partition wall 2f.
The maximum diameter portion of the snail 2l is larger than the inner diameter of the packing 2k.

The tip of a slant 21 of this type may be flat. In that case, a rubber plate is attached to the tip of the slant 2l, and the hole 2j
If the inner diameter of the float is reduced, the buoyancy of the float 2c
The water pressure flowing down from the hole 2j can be sufficiently stopped.
Further, instead of causing the buoyancy of the float 2c to act on the hole 2j via the sled 21, the buoyancy may be amplified to act by applying the leverage principle.

In any type of water level controller 2, a fixed position between the outer wall 1c and the inner wall 1d of the flower pot 1, that is, the water outlet 2e of the water level controller 2 overlaps the water inlet 1g of the culture soil accommodating portion 1a. The rubber sheet 3 is pressure-bonded and fixed in position.

In the plant pot 1 in which the water level controller 2 is housed in this way, as shown in FIG.
The culture soil 4 is put in a, and the plant 5 is planted. After that, the water tank portion 1b is filled with water.

The water flows from the water inlet 2d of the water level controller 2 through the filter 2h into the float housing 2a. Then, in the case of the type shown in FIGS. 4 to 7, the partition wall 2f passes through the gap between the bottom of the hole 2j and the snail 2l and overflows upward. Then, it flows out from the filter 2i and the water outlet 2e into the culture soil accommodating portion 1a through the water inlet 1g. The water permeates the culture soil 4 and once permeates it, and then accumulates in the lower portion of the culture soil accommodating portion 1a and the water reservoir portion 1f.
To form At that time, the float accommodating portion 2 of the water level controller 2
The water level in a also rises, and the float 2c rises and the slant 21 rises accordingly. Then, the snail 2l abuts the annular packing 2k of the hole 2j to close the hole 2j. As a result, the outflow of water from the hole 2j is stopped, and the culture soil container 1
The water level of a is kept constant. The type shown in FIGS. 8 to 11 is almost the same except that the flow of water in the hole 2j is reversed.

The water accumulated in the water reservoir 1f of the culture soil accommodating portion 1a is absorbed into the culture soil as the culture soil loses water due to evaporation and evaporation. And the water reservoir 1
When the water level of f goes down, the water level inside the water level controller 2 also goes down,
Along with that, the float 2c and the slant 2l are lowered again, and the partition wall 2
The hole 2j of f becomes water-permeable, and water is supplied in the same manner as described above. Further, excess water such as rain is discharged from the overflow port 1e. In addition, when the flower pot is placed indoors, it is not exposed to rain, and thus the overflow port 1e may be used with the lid covered.

In the above description, the water level adjuster 2 is used as an automatic water supply means from the water storage tank portion 1b to the culture soil accommodating portion 1a, but instead of this, the culture soil in the culture soil accommodating portion 1a is used. The water supply motor is driven based on the degree of wetness (measured by electric resistance or the like), or the water reservoir 1f is formed in the culture soil accommodating portion 1a, it is turned on or off depending on the water level. You may make it drive a water supply motor using a limit switch.

[0025]

Since the present invention is configured as described above, it has the following effects.

That is, it is possible to automatically irrigate the culture soil in the flowerpot without requiring any electric power or manpower,
The moistness of the culture soil can be kept almost constant at all times. Therefore, the optimum rooting state of the plant is obtained, the growth is promoted, and the root rot and the overgrowth do not occur. In addition, there is no need for watering, no skill is required, and there is no loss of fertilizer due to watering. Also, since the upper part of the water tank part is opened, the structure of the water tank part can be simplified, and the shape of the flowerpot can be freely determined. It's very easy. Moreover, even if the material is opaque, the water level in the water tank can be seen from above, so the timing of replenishing water will not be missed.

[Brief description of drawings]

FIG. 1 is a perspective view of a flower pot of the present invention.

FIG. 2 is a perspective view of the water level controller of the present invention.

FIG. 3 is a vertical cross-sectional view showing a planted state of the flower pot of the present invention.

FIG. 4 is a vertical sectional view of the water level controller of the present invention.

5 is a vertical cross-sectional view of the water level controller of the present invention in a direction orthogonal to FIG.

6 is a cross-sectional view taken along the line A-A ′ in FIG.

FIG. 7 is a diagram showing the relationship between the float and the holes of the partition wall of the water level controller of the present invention.

FIG. 8 is a longitudinal sectional view of another type of water level controller of the present invention.

9 is a longitudinal sectional view of another type of water level controller of the present invention in a direction orthogonal to FIG.

10 is a cross-sectional view taken along the line A-A ′ in FIG.

FIG. 11 is a view showing a relationship between a float and a hole of a partition wall of another type of water level controller of the present invention.

[Explanation of symbols]

 1 Flower Pot 1a Culture Soil Storage 1b Water Tank 1e Overflow Port 1f Water Storage 1g Water Outlet 2 Water Level Controller 2c Float 2d Water Inlet 2e Water Outlet 2f Partition 2j Hole 2l Pond

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[Procedure amendment]

[Submission date] November 21, 1996

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction contents]

[Document Name] Statement

[Title of Invention] Flowerpot and water level controller

[Claims]

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flowerpot (including a box-shaped one, that is, a planter) provided with a water storage tank and a water level adjuster used therein.

[0002]

2. Description of the Related Art Conventionally, as an automatic watering device for flower pots,
It is known to supply water for a time with a hose laid from a water supply.

[0003]

SUMMARY OF THE INVENTION The above automatic irrigation system has difficulty in supplying an appropriate amount of water corresponding to the weather (rainy weather, cold and warm) of the day, is likely to be too wet or too dry, and drives the system. It also requires electricity.

It is an object of the present invention to automatically irrigate the culture soil in a flowerpot and maintain the moistness of the culture soil substantially constant without requiring any manual labor or electric power.

[0005]

The flowerpot of the present invention has a culture soil accommodating portion 1a and a water storage tank portion 1b having an open upper portion for automatically supplying water to the culture soil accommodating portion 1a. .

In a plant pot having a culture soil storage portion 1a and a water storage tank portion 1b for automatically supplying water to the culture soil storage portion 1a, an overflow port protruding upward in a cylindrical shape at the bottom of the culture soil storage portion 1a. It is advisable to form the portion 1e to serve as a water reservoir 1f for accumulating water in the water tank portion 1b.

The water level controller 2 is adapted to open and close a water supply passage 2j in a flowerpot 1 having a culture soil accommodating portion 1a and a water storage tank portion 1b by utilizing the buoyancy of the float 2c.

[0008] A typical flower pot has a cylindrical shape with the bottom facing upward.
A culture soil accommodating portion 1a having a protruding overflow portion 1e,
The water tank portion 1b communicates with a water supply channel (2j, etc.),
The water supply passage 2j is opened by utilizing the buoyancy of the built-in float 2c.
The water level controller 2 to be closed is housed in the water tank 1b.
It is.

[0009]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of a flower pot and a water level controller used therein according to the present invention will be described with reference to FIGS.

This flower pot 1 is generally equipped with a culture soil storage section 1a.
And a water tank portion 1b. Also, the water level controller 2
Is stored in the water storage tank portion 1b of the flower pot 1 in order to keep the water level of the culture soil storage portion 1a (water storage portion 1b) constant.

The flower pot 1 has a bottomed cylindrical shape, a box shape or the like, and the shape thereof is not particularly limited. The material may be any material, such as synthetic resin, ceramics, and metal, as long as water does not exude.

In the flower pot 1 shown in FIGS. 1 and 3, the outer wall 1c and the inner wall 1d are doubly circulated, and the space between them serves as a water tank portion 1b. However, the water storage tank portion 1b does not necessarily have to be arranged so as to surround the culture soil accommodating portion 1a, and may be arranged on one side of the culture soil accommodating portion 1a. In short,
The culture soil accommodating portion 1a and the water storage tank portion 1b may be open above. By doing so, the structure of the water storage tank portion 1b can be simplified. Further, the shape of the flower pot can be freely determined, and when it is made of plastic, its molding is extremely easy. In addition, even if the material is opaque, the water level in the water tank portion 1b can be seen from above, so the timing of replenishing water will not be missed.

On the wall surface 1d below the culture soil container 1a,
A water inlet 1g leading to the water tank portion 1b is provided.

The bottom of the culture soil accommodating portion 1a is provided with an overflow port portion 1e projecting upward in a cylindrical shape. A portion below the position slightly lower than the upper end of the overflow port portion 1e serves as a water reservoir portion 1f in which water flowing out from the water storage tank portion 1b via the water level adjuster 2 is accumulated. The water level of the water reservoir 1f is determined by the position setting of the float 2c of the water level adjuster 2 described later. The overflow port 1e can be covered with a lid with packing. This is effective when the flowerpot is placed in a place where water should not be spilled, such as indoors. When the flower pot is placed outdoors, the lid may be removed because it may be rained and water may become excessive.

The water level adjuster 2 accommodates a float 2c, has a water inlet 2d and a water outlet 2e, and is a space which is a space separated by a partition 2f having an L-shaped hole. It is composed of a tubular portion 2b which communicates with the upper portion thereof and extends at least to the upper end position of the container 1 and which has a vent hole 2g in the upper portion.

The water inlet 2d and the water outlet 2e are provided with filters 2h and 2i which are in close contact with each other to prevent the infiltration of the culture soil. A hole 2j is formed at the bottom of the partition wall 2f, and an annular packing 2k such as rubber is attached to the hole 2j.

The float 2c is integrated with a sled 2l whose main portion is conical, but there are two types depending on the difference in the relationship between the sled 2l and the packing 2k.

One is the float 2c shown in FIGS.
Is provided on the upper side of the partition wall 2f, and the sled 2l is attached to the lower surface thereof. As shown in FIG. 7, the snout 2l has a lower end protruding below the hole 2j of the partition wall 2f. The outer diameter of the lowermost end of the snail 2l is larger than the inner diameter of the packing 2k, and gradually decreases as it goes upward through a portion equal to the inner diameter of the packing 2k. However, the integrated portion with the float 2c has a constant diameter.

The other is that the float 2c shown in FIGS. 8 to 11 is provided below the partition wall 2f, and the slant 2l is provided on the upper surface thereof.
Is installed. As shown in FIG. 11, the upper end of the slant 2l is applied to the hole 2j of the partition wall 2f.
The maximum diameter portion of the snail 2l is larger than the inner diameter of the packing 2k.

The tip of this type of snail 2l may be flat. In that case, a rubber plate is attached to the tip of the slant 2l, and the hole 2j
If the inner diameter of the float is reduced, the buoyancy of the float 2c
The water pressure flowing down from the hole 2j can be sufficiently stopped.

In any type of water level regulator 2, a fixed position between the outer wall 1c and the inner wall 1d of the flower pot 1, that is, the water outlet 2e of the water level regulator 2 overlaps the water inlet 1g of the culture soil accommodating portion 1a. The rubber sheet 3 is pressure-bonded and fixed in position.

In the plant pot 1 in which the water level controller 2 is housed in this way, as shown in FIG.
The culture soil 4 is put in a, and the plant 5 is planted. After that, the water tank portion 1b is filled with water.

The water flows from the water inlet 2d of the water level controller 2 through the filter 2h into the float accommodating portion 2a. Then, in the case of the type shown in FIGS. 4 to 7, the partition wall 2f passes through the gap between the bottom of the hole 2j and the snail 2l and overflows upward. Then, it flows out from the filter 2i and the water outlet 2e into the culture soil accommodating portion 1a through the water inlet 1g. The water permeates the culture soil 4 and once permeates it, and then accumulates in the lower portion of the culture soil accommodating portion 1a and the water reservoir portion 1f.
To form At that time, the float accommodating portion 2 of the water level controller 2
The water level in a also rises, and the float 2c rises and the slant 21 rises accordingly. Then, the snail 2l abuts the annular packing 2k of the hole 2j to close the hole 2j. As a result, the outflow of water from the hole 2j is stopped, and the culture soil container 1
The water level of a is kept constant. The type shown in FIGS. 8 to 11 is almost the same except that the flow of water in the hole 2j is reversed.

The water thus collected in the water reservoir 1f of the culture soil accommodating portion 1a is absorbed into the culture soil as the culture soil loses water by evaporation and evaporation. And the water reservoir 1
When the water level of f goes down, the water level inside the water level controller 2 also goes down,
Along with that, the float 2c and the slant 2l are lowered again, and the partition wall 2
The hole 2j of f becomes water-permeable, and water is supplied in the same manner as described above. Further, excess water such as rain is discharged from the overflow port 1e. In addition, when the flower pot is placed indoors, it is not exposed to rain, and thus the overflow port 1e may be used with the lid covered.

[0025]

Since the present invention is configured as described above, it has the following effects.

That is, it is possible to automatically irrigate the culture soil in the flowerpot without requiring any electric power or manpower,
The moistness of the culture soil can be kept almost constant at all times. Therefore, the optimum rooting state of the plant is obtained, the growth is promoted, and the root rot and the overgrowth do not occur. In addition, there is no need for watering, no skill is required, and there is no loss of fertilizer due to watering. Also, since the upper part of the water tank part is opened, the structure of the water tank part can be simplified, and the shape of the flowerpot can be freely determined. It's very easy. Moreover, even if the material is opaque, the water level in the water tank can be seen from above, so the timing of replenishing water will not be missed.
Since the water level controller has a built-in float, it is compact
Yes, easy to assemble and handle, and highly reliable. Ma
Also, if an overflow port is to be provided at the bottom of the culture soil storage unit,
If you put a wooden pot outdoors and it rains
If you cover the overflow port with a lid, water spilled indoors etc.
Can be placed in places where it should not be.

[Brief description of drawings]

FIG. 1 is a perspective view of a flower pot of the present invention.

FIG. 2 is a perspective view of the water level controller of the present invention.

FIG. 3 is a vertical cross-sectional view showing a planted state of the flower pot of the present invention.

FIG. 4 is a vertical sectional view of the water level controller of the present invention.

5 is a vertical cross-sectional view of the water level controller of the present invention in a direction orthogonal to FIG.

6 is a cross-sectional view taken along the line A-A ′ in FIG.

FIG. 7 is a diagram showing the relationship between the float and the holes of the partition wall of the water level controller of the present invention.

FIG. 8 is a longitudinal sectional view of another type of water level controller of the present invention.

9 is a longitudinal sectional view of another type of water level controller of the present invention in a direction orthogonal to FIG.

10 is a cross-sectional view taken along the line A-A ′ in FIG.

FIG. 11 is a view showing a relationship between a float and a hole of a partition wall of another type of water level controller of the present invention.

[Explanation of Codes] 1 Flower pot 1a Culture soil storage part 1b Water tank part 1e Overflow part 1f Water reservoir part 1g Water outlet 2 Water level controller 2c Float 2d Water inlet 2e Water outlet 2f Partition wall 2j Hole forming part of water supply channel 2l Snoop

Claims (3)

[Claims] 1. A flower pot having a culture soil storage portion and a water tank portion having an open upper portion for automatically supplying water to the culture soil storage portion. 2. A culture soil accommodating portion and a water storage tank portion for automatically supplying water to the culture soil accommodating portion, and an overflow port projecting upward in a cylindrical shape is formed at the bottom of the culture soil accommodating portion. A flowerpot that serves as a water reservoir for the water in the water tank. 3. A water level controller which opens and closes a water supply channel in a flowerpot having a culture soil accommodating section and a water tank section by utilizing the buoyancy of a float.