KR101874093B1 - Smart flower pot - Google Patents

Abstract

The present invention relates to a smart flower pot, and more specifically, to a smart flower pot, in which a moisture sensor installed therein measures content of moisture in the flower pot, and according to the measured content of moisture, the flower pot is enabled to automatically ascend or descend. For the purpose, the present invention provides a smart flower pot comprising: a planting unit (100) having a moisture sensor (110) inserted into soil, where a vegetation is planted, to measure content of moisture present in the soil; a support unit (200) having a display window (220) disposed in the lower part of the planting unit (100) to display the moisture content measured by the moisture sensor (110); an elastic means (300) having one end joined and fixed to the upper part of the support unit (200) and the other end joined and fixed to the lower part of the planting unit (100) to support the planting unit (100) and simultaneously transfer the planting unit (100) elastically upward, and having a wire fixing end (330) formed on the upper part of the outer circumference; a driving unit (400) composed of a motor (410) installed inside the support unit (200) and a rotational shaft (420) connected to a driving shaft (412) of the motor (410) to have pulleys (430) installed on both ends thereof; a wire (500) having two ends fixed respectively to the wire fixing end (330) and the pulley (430), wherein the wire (500) is wound up or unwound around the pulley (430) in a rotational direction when the pulley (430) rotates due to driving force of the motor (410); and a control unit (600) receiving a measurement value from the moisture sensor (110) and comparing the same with a reference value to control the motor (410) according to the comparison result, thereby making the planting unit (100) descend.

Description

Smart flower pot {Smart flower pot}

The present invention relates to smart pots, and more particularly, to smart pots that measure the water content of a pot through a water sensor installed inside the pot and automatically raise or lower the pot according to the measured water value.

Pollen is basically a plant cultivation vessel that plants plants and supplies soil and water in it to provide a suitable growing space. In order to grow the plant in the pot, the most important thing is to supply the water smoothly, and in order to do this, the user needs to supply the proper moisture according to the water requirement of the plant planted in the pot.

However, if the pollen does not supply enough moisture for the required time required for the water, the plant will eventually die and, at the same time, supply moisture at the proper time, which is troublesome for the user.

Therefore, in order to overcome such a problem, a pot with a water supply space is used, and a stone, a styrofoam, and other members are filled at the bottom of the pot, and the soil is filled at the top of the pot, Which is well known in the art.

On the other hand, as one of these techniques, a 'natural watering potted plant' is known in Korean Registered Utility Model No. 20-0257503.

In the above technique, a water supply tank with water is located at the lower part of the flowerpot and serves to supply water to the root part of the flowerpot. A drainpipe is formed upwardly in the bottom of the flowerpot body and a drainpipe is formed at the upper end of the waterpipe, A water tank for storing water according to the height of the drain pipe is provided at the lower part and a water supply pipe is formed at a position slightly higher than the position of the water pipe drain pipe and a water level indicator is attached to the side of the water supply pipe, So that the user can easily identify the storage amount.

However, although the above-described technique allows the user to adjust the water volume while checking the water level, it is inconvenient to water the water on a scale, and if the user accidentally overflows water beyond the limit of the water level indicator, There was a problem of blocking the soil pore (soil pore).

Therefore, as a technique for solving the above problems, Korean Utility Model Application No. 20-2014-0003739 discloses a motor-driven rotary pot pot.

The above description is based on a base installed in contact with or in close proximity to the ground; A frame provided above the base and including vertical support rods erected on both left and right sides; A first upper sprocket and a second upper sprocket supported on the frame and spaced apart from each other in a horizontal direction; An upper rotating shaft extending in the horizontal direction through the centers of the first upper sprocket and the second upper sprocket; An electric motor for rotating the upper rotary shaft; A first lower sprocket disposed at a lower portion of the first upper sprocket by a first distance and a second lower sprocket spaced a first distance below the second upper sprocket; A first chain connected to the first upper sprocket and the first lower sprocket and rotating in an endless track; A second chain connected to the second upper sprocket and the second lower sprocket and rotating in an endless track; A plurality of potting bars installed in the lateral direction between the first chain and the second chain; And a plurality of pots suspended from the respective potting rods; And a controller for controlling the operation of the electric motor. It is an object of the present invention to enable the management of plants planted in pots and the supply of water more conveniently.

However, since the above-described technique can rotate the chains installed in the up and down direction by an electric motor to change the positions of the pollen pots, maintenance of the pollen can be easily performed, but it is structured with a very complicated structure. It is very likely to be easily damaged and has a problem that it is not suitable for landscape use because the installation space is large and the appearance is not so good.

Korean Public Utility Model No. 20-2014-0003739 (Published on June 18, 2014) Korean Registered Patent No. 10-1542890 (Registered on August 3, 2015) U.S. Published Patent Application No. 2002-0024445 (published Feb. 28, 2002)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a water supply system, in which a user can visually check the water content of a flowerpot, The present invention provides a smart flowerpot which is designed in a simple structure and is beautiful in appearance and can give a sense of aesthetics to a user.

Another object is to provide smart pots that meet different water requirements according to the type of plant, thereby expanding versatility.

In order to accomplish the above object, the present invention provides a planting part 100 having a moisture sensor 110 inserted into a soil planted with plants and measuring the amount of water present in the soil; A pedestal 200 provided at a lower portion of the planting portion 100 and having a display window 220 for displaying a moisture content measured by the moisture sensor 110; One end is fixedly coupled to the upper part of the support part 200 and the other end is fixedly coupled to the lower part of the planting part 100 to support the planting part 100 and move the planting part 100 upward An elastic means (300) having a wire fixing end (330) formed on its upper outer periphery; A driving unit 400 including a motor 410 installed in the receiving unit 200 and a rotating shaft 420 connected to the driving shaft 412 of the motor 410 and provided with pulleys 430 at both ends thereof; Both ends of the wire 410 are fixed to the wire fixing end 330 and the pulley 430 and the pulley 430 is rotated by the driving force of the motor 410 so that the wire wound around the pulley 430 500); And a control unit 600 for comparing the measured value of the moisture sensor 110 with a preset reference value and controlling the motor 410 according to the result to lower the planting unit 100 .

The control unit 600 is connected to the moisture sensor 110 and the motor 410 and calculates the measured value of the moisture sensor 110 and the set reference value, And a reference value DB 610 connected to the controller 620 and storing the reference value.

The elastic means 300 includes a cylinder 340 filled with gas, a piston 310 reciprocating in a state of being inserted into the cylinder 340, and a piston 310 integrally connected with the piston 310, And a piston rod 320 for guiding the reciprocating motion of the piston rod 320. The piston rod 320 is provided at its outer periphery with a graduation 322) are displayed.

On the other hand, in the inside of the receiving unit 200, a weight 230 is installed on one side of the other area excluding the area where the drive unit 400 is installed, so that the receiving unit 200 does not arbitrarily move on the mounting surface At least one of the receiving unit 200 and the control unit 600 may include a lamp or an acoustic facility for informing the outside of the measured value of the moisture sensor 110 when the measured value is low. The input means 210 may be formed so that the moisture reference value can be manually set on one side of the outer circumferential surface.

The smart pot flower of the present invention having the above-

First, since the structure of the pollen height is changed by the detection of the moisture sensor, the user can easily check the water content of the pollen with the naked eye, so that the water supply mechanism can be smoothly performed. In addition, Experience can be provided,

Secondly, it is designed with simple structure and beautiful appearance, giving a sense of aesthetics to the user, and can be used as a decorative article in the home to enhance the aesthetic appearance,

Third, it has the effect of expanding the versatility by meeting different water requirement according to the kinds of plants.

1 is a perspective view showing a smart flower pot according to a preferred embodiment of the present invention;
2 is a cross-sectional side view of a smart flower pollen according to a preferred embodiment of the present invention.
FIG. 3 is a use state diagram showing a state where the smart pot is raised and lowered according to a preferred embodiment of the present invention. FIG.
4 is a flow chart illustrating an operational flow of a smart flower pot according to a preferred embodiment of the present invention.
FIG. 5 is a schematic diagram showing a control flow of a smart flower pot according to a preferred embodiment of the present invention; FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a smart pot according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in the figure, the smart pot flower according to the present invention,

A planting part (100) provided with a moisture sensor (110) inserted into a soil where plants are planted and measuring the amount of water present in the soil;

A pedestal 200 provided at a lower portion of the planting portion 100 and having a display window 220 for displaying a moisture content measured by the moisture sensor 110;

One end is fixedly coupled to the upper part of the support part 200 and the other end is fixedly coupled to the lower part of the planting part 100 to support the planting part 100 and move the planting part 100 upward An elastic means (300) having a wire fixing end (330) formed on its upper outer periphery;

A driving unit 400 including a motor 410 installed in the receiving unit 200 and a rotating shaft 420 connected to the driving shaft 412 of the motor 410 and provided with pulleys 430 at both ends thereof;

Both ends of the wire 410 are fixed to the wire fixing end 330 and the pulley 430 and the pulley 430 is rotated by the driving force of the motor 410 so that the wire wound around the pulley 430 500); And

And a control unit 600 for comparing the measured value of the moisture sensor 110 with a preset reference value and controlling the motor 410 according to the result to lower the planting unit 100.

As shown in FIG. 1, the planting part 100 is filled with soil at a predetermined height inside a pot-shaped container, and plants are planted in the soil. A plant to be planted in the planting section 100 may be planted in the planting section 100 according to the user's selection.

A moisture sensor (110) for measuring the moisture content in the soil is provided in the planting part (100). The moisture sensor 110 is electrically connected to the controller 620 and transmits moisture values measured by the moisture sensor 110 to the controller 620. The moisture value measured by the moisture sensor 110 and transferred to the controller 620 is converted into a control signal to perform various commands.

The moisture sensor 110 may include an electrode rod having a pair of different electrodes therein and connected in series. The electrode may measure the moisture value depending on the water content of the soil between both ends of the electrode, and may transmit the moisture value to the controller 620.

As a further example, in order to prevent water from flowing backward in the planting section 100 when water is excessively supplied to the inside of the planting section 100, A plurality of through holes may be formed in a lower portion of the through hole and a flowerpot support may be provided to contain moisture discharged downward through the through holes.

The receiving unit 200 is provided at a lower portion of the planting unit 100 and a display window 220 is formed on one side of the receiving unit 200 to display a moisture amount measured by the moisture sensor 110. 1 to 3, the receiving unit 200 is located on a target surface to be mounted and supports the planting unit 100 provided on the receiving unit 200 .

2, a weight 230 having a high specific gravity may be installed in the receiving portion 200 for tightly contacting the receiving portion 200 by applying a load to the receiving portion 200 . In this case, when the weight 230 is installed inside the receiving unit 200, it is preferable to install the weight 230 so as not to interfere with various parts contained in the receiving unit 200.

As an additional example, an input unit 210 may be formed on one side of the outer circumferential surface of the receiving unit 200. The input unit 210 may include, for example, a plant having a high water- The user can arbitrarily set the moisture reference value.

The display window 220 formed on the receiving unit 200 may display various information that may affect not only the moisture content of the planting unit 100 but also the surrounding humidity, So that the user can recognize this.

As another example of the addition, the display window 220 may be utilized as an input means, and an electrostatic or pressure sensitive touch panel may be applied to the display window.

The elastic means 300 connects the planting unit 100 and the support unit 200 to firmly support the planting unit 100 and move the planting unit 100 upward . To this end, one end of the elastic means 300 is fixedly coupled to the upper part of the receiving part 200, and the other end is fixedly coupled to the lower part of the planting part 100.

The elastic means 300 may be formed of a gas shock absorber or a gas spring which is commonly used and has elasticity sufficient to push the planting portion 100 connected to the other end of the elastic means 300 upward It is preferable to use something with.

2, the elastic means 300 includes a cylinder 340 filled with a gas and a piston 350 reciprocating in a state of being inserted into the cylinder 340 And a piston rod 320 integrally connected to the piston 310 and guiding the reciprocating motion of the piston 310. A wire fixing end 330 is formed on one side of the upper outer periphery of the piston rod 320. The wire fixing end 330 is formed on at least two points so that the wire 500 is fixed to the wire fixing end 330. [ It is desirable to be able to balance when fixed.

A scale 322 may be displayed on the piston rod 320 at regular intervals in a direction perpendicular to the outer periphery of the piston rod 320. This allows the user to adjust the lifted position of the planting portion 100 through the scale 322 So as to facilitate identification. In addition, the scale 322 may be formed in a number of 5 to 10 cm intervals as one embodiment.

2, the drive unit 400 includes a motor 410 supported by a support unit inside the support unit 200, and a drive shaft 412 connected to the drive shaft 412 of the motor 410, And a rotary shaft 420 provided with a pulley 430.

The motor 410 may be electrically connected to a power source, and may receive a command signal from the controller 620 to maintain a normal rotation, a reverse rotation, or a stop state. The pulleys 430 are formed in a pulley shape and installed at both ends of the rotating shaft 420 to wind or unwind the wires 500 to be described later.

The wire 500 is fixed at its both ends to the wire fixing end 330 and the pulley 430 so that the pulley 430 installed at the rotation axis 420, which is combined with the motor 410, The pulley 430 is rotated in one direction along the rotation direction by the rotation of the pulley 430 and the wire 500 connected to the pulley 430 is also wound on the pulley 430 as the pulley 430 is rotated It is released.

In other words, when the wire 500 is wound on the pulley 430, the piston rod 320, which is one of the components of the elastic means 300, is depressurized The state shown in Fig. 3 (b) can be maintained. Conversely, when the wire 500 rotates in a direction opposite to the rotation direction of the motor 410 when the wire 500 is wound around the pulley 430, or when the motor 410 reaches a stop state, So that the wire 500 wound on the pulley 430 is unwound and elastically moved upward. Thus, the planting portion 100 fixedly coupled to the elastic means 300 is simultaneously lifted.

The control unit 600 is connected to the moisture sensor 110 and the motor 410 and calculates a measured value of the moisture sensor 110 and a set reference value, And a reference value DB 610 connected to the controller 620 and storing the reference value.

The controller 600 compares the measured value of the moisture sensor 110 with a predetermined reference value and controls the motor 410 according to the measured value to lower the plant 100. For example, , And controls the motor (410) to operate when the moisture value received from the moisture sensor (110) is less than a predetermined reference value by comparing the moisture value received from the moisture sensor (110) 410 to stop the operation of the control unit.

For example, when the maximum rising height and the minimum falling height of the planting unit 100 are divided into seven sections at a 10% interval in a range of 20 to 80% set in the controller 600, if the moisture value is 80% The motor 410 is stopped so that the planting unit 100 is positioned at the maximum elevation height and when the moisture value is 70% In the case where the moisture value is 20% through such a series of operations, the planting portion 100 can be positioned at the lowest height. Accordingly, since the user can visually confirm the height of the planting portion 100 even at a long distance, the user can easily grasp the moisture value of the planting portion 100, and when the plant reaches the minimum height, the planting portion 100 Since it is located at a low point, it is advantageous to supply moisture. Further, the planting section 100 is in the middle section. That is, even when the user is located in four out of seven sections, the user can check the current percentage of the moisture content in the planting section 100.

Setting the range of the moisture value and the height of the point at which the planting unit 100 is located in the stepwise manner according to the range of the moisture value is performed by setting the value of the moisture value sensor 610 on the basis of the preset value in the reference value DB 610 And compares the measured values and controls the motor 410 according to the result.

In addition, when the control unit 600 generates and transmits the driving signal as described above, a sensor capable of sensing the value of the driving shaft 412 of the motor 410 may be additionally provided in the receiving unit 200. For example, assuming that the drive shaft 412 of the motor 410 rotates three times to lower the planting member 100 by 10 cm, the sensor senses the rotation value of the drive shaft 412 of the motor 410, The operation can be stopped when the rotation of the three wheels 412 is completed.

5, the user can arbitrarily set the moisture reference value through the input unit 210 connected to the control unit 600, in order to meet different moisture requirements depending on the type of plant.

As a further embodiment, when the planting unit 100 is lowered to the maximum, a lamp or a lamp installed in at least one of the receiving unit 200 and the control unit 600 without a user directly checking in a dark place or with the naked eye It is possible to recognize that the planting portion 100 is in a state of lacking water through an acoustic facility or the like.

According to the present invention configured as above, the height of the pollen can be varied by sensing the water sensor, so that the user can easily check the water content of the pollen with the naked eye to smoothly perform the water supply mechanism, It is possible to provide a new experience to users in plant cultivation, to be designed with a simple structure, to have a beautiful appearance, to give a sense of aesthetics to a user, to be used as a decorative article at home, It is a very useful invention that can satisfy various moisture requirements according to the water content and expand the versatility.

100: planting part 340: cylinder
110: Moisture sensor 400: Drive unit
200: receiving portion 410: motor
210: Input means 412:
220: display window 420:
230: weight 430: pulley
300: elastic means 500: wire
310: piston 600:
320: Piston rod 610: Reference value DB
322: scale 620: controller
330:

Claims (6)

A planting part (100) provided with a moisture sensor (110) inserted into a soil where plants are planted and measuring the amount of water present in the soil;
A pedestal 200 provided at a lower portion of the planting portion 100 and having a display window 220 for displaying a moisture content measured by the moisture sensor 110;
One end is fixedly coupled to the upper part of the support part 200 and the other end is fixedly coupled to the lower part of the planting part 100 to support the planting part 100 and move the planting part 100 upward An elastic means (300) having a wire fixing end (330) formed on its upper outer periphery;
A driving unit 400 including a motor 410 installed in the receiving unit 200 and a rotating shaft 420 connected to the driving shaft 412 of the motor 410 and provided with pulleys 430 at both ends thereof;
Both ends of the wire 410 are fixed to the wire fixing end 330 and the pulley 430 and the pulley 430 is rotated by the driving force of the motor 410 so that the wire wound around the pulley 430 500); And
And a controller 600 for comparing the measured value of the moisture sensor 110 with a preset reference value and controlling the motor 410 according to the result to lower the planting unit 100 Smart potted plants. The method according to claim 1,
The control unit 600 is connected to the moisture sensor 110 and the motor 410 and calculates a measured value of the moisture sensor 110 and a set reference value, And a reference value DB (610) connected to the controller (620) and storing the reference value. The method according to claim 1,
The elastic means 300 includes a cylinder 340 filled with gas, a piston 310 reciprocating in a state of being inserted into the cylinder 340, and a piston 310 integrally connected to the piston 310, And a piston rod 320 for guiding reciprocating motion of the piston rod 320,
And a scale (322) is displayed at regular intervals in the vertical direction so as to identify the ascending and descending positions of the planting part (100) on the outer periphery of the piston rod (320). The method according to claim 1,
A weight 230 is installed inside the support part 200 so that the support part 200 does not arbitrarily move on the installation target surface on one side of the remaining area except the area where the drive unit 400 is installed. Smart potted plants. The method according to claim 1,
Wherein at least one of the receiving unit (200) and the control unit (600) comprises a lamp or an acoustic facility for informing the outside of the measurement value of the moisture sensor (110) when the measured value is low. The method according to claim 1,
Wherein the receiving unit (200) is provided with input means (210) for manually setting a moisture reference value on one side of the outer circumferential surface.

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