CN212813372U - Indoor green plant intelligence device that waters - Google Patents

Abstract

The utility model discloses an indoor green plant intelligence device that waters, including support portion, water storage portion, control part, power supply portion, monitoring portion and drain pipe, the water storage portion bottom is connected with support portion, and the upper end is connected with power supply portion, and inside control part and the detection portion set up water storage portion, the drain pipe setting was in the water storage portion outside. The utility model discloses can water to green planting of many basins, the green watering volume of planting and the cycle of watering of planting to every basin have pertinence moreover, can combine the corresponding green watering of planting of article type habit according to soil moisture to carry out the watering of different cycles and water yield, can also remind the user moisturizing through cell-phone end APP when the storage water tank does not have water simultaneously, the utility model discloses solar cell economize on electricity environmental protection has still been used.

Description

Indoor green plant intelligence device that waters

Technical Field

The utility model relates to a green maintenance field of planting, concretely relates to indoor green intelligent device that waters of planting.

Background

More and more people now like to cultivate some ornamental green plants indoors, but sometimes go out of business or cannot timely return to the care of the green plants when an emergency happens, the green plants can die due to water shortage, and spiritual attack and property loss are brought to cultivators. Although some automatic flower watering devices are already available in the market at present, the devices are not intelligent enough, watering can not be performed according to the humidity of soil, the varieties and habits of green plants cannot be watered, for example, some desert green plants need to be cultivated in slightly dry soil, and watering is not required frequently. In conclusion, a novel intelligent watering device is needed to be designed, on the basis of intelligent watering according to the humidity of soil, the watering can be performed in a targeted mode according to the variety and the habit of green plants, and one device can be used for multiple-pot green plants.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a solve above-mentioned problem, designed an indoor green intelligence device that waters of planting.

In order to solve the above technical problem and achieve the above technical effect, the utility model discloses a following technical content realizes:

an indoor intelligent watering device for green plants comprises a support part, a water storage part, a control part, a power supply part, a monitoring part and a drain pipe, wherein the bottom end of the water storage part is connected with the support part, the upper end of the water storage part is connected with the power supply part, the control part and the detection part are arranged in the water storage part, and the drain pipe is arranged outside the water storage part;

the support part comprises a chassis and four telescopic supporting legs with adjustable heights, the effect of adjusting the height of the water storage part can be realized, and one ends of the four telescopic supporting legs are welded on the chassis; the other end is welded at the bottom of the water storage part to connect the support part with the water storage part;

the water storage part comprises a water storage chamber, a water discharge hole, an electromagnetic valve and a water injection port device cavity; the water storage chamber is a cylindrical cavity, the water discharge hole is formed in the bottom of the water storage chamber, the electromagnetic valve is installed on the water discharge hole to control water circulation, and the semicircular water injection port is formed in the top of the water storage chamber to facilitate water injection into the water storage chamber; the device cavity is positioned on one side in the water storage chamber and is a semicircular hollow cavity, and a control part is arranged in the device cavity;

the control part comprises a controller, a single chip microcomputer, a WIFI module, a cloud server and a mobile phone APP control module; the controller is positioned in the device cavity, and the singlechip and the WiFi module are integrated on the controller; the WIFI module is in bidirectional connection with the single chip microcomputer, and is in communication connection with the mobile phone APP control module through the cloud server;

the power supply part comprises a solar panel, a storage battery and a power line; the solar cell panel is positioned at the top of the water storage chamber, the storage battery is positioned in the device cavity, the storage battery is provided with a power line, the solar cell can store electricity for the storage battery under the condition of illumination, and the storage battery can be externally connected with a power supply through the power line to store electricity under the condition of long-time cloudy days;

the monitoring part comprises a camera, a flow sensor and a soil humidity sensor; the camera is arranged on a circular ring outside the water storage chamber, the flow monitoring sensor is arranged in the drainage hole, and the soil humidity sensor is arranged at the tail end of the drainage pipe;

the camera, the flow sensor and the soil humidity sensor are all provided with lines to be connected with the single chip microcomputer and the storage battery.

Furthermore, the number of the drain holes is 16, and the drain holes are annularly arranged on the inner wall of the bottom of the water storage chamber at equal intervals; each drain hole is provided with an independent electromagnetic valve, and each drain hole is internally provided with a flow monitoring sensor.

Furthermore, the number of the drain pipes is 16, and each tail end is provided with a soil humidity sensor.

Further, the single chip microcomputer adopts an STM32 series microcontroller STM32F103VET6 based on an ARMCortex-M3 inner core.

Furthermore, WIFI module, high in the clouds server and cell-phone APP control module, accessible cell-phone APP control module visit high in the clouds server and carry out remote control watering.

Further, the camera can monitor and shoot, and accessible cell-phone APP control module visits high in the clouds server and monitors the growth environment change that flowers and plants are cultivated in a pot in real time.

The utility model has the advantages that:

(1) the utility model can water a plurality of pots of green plants, 16 water outlets are arranged at the bottom of the water storage chamber, users can insert the water outlet pipe into the plant flowerpot to be watered according to the number of cultivated plants, thereby solving the problem that the traditional automatic watering device can only water a small amount of plants;

(2) the utility model can adjust the watering amount and the watering period of each green plant in a targeted way by integrating the current quite popular and mature picture identification technology, cloud service technology and network communication technology, and can irrigate with different periods and water amounts according to soil humidity and corresponding green plant species habits;

(3) the utility model can remind the user of water supplement through the APP at the mobile phone end when the water storage tank is empty of water, thereby avoiding the problem that the water stored by the traditional automatic watering device is used up and the user forgets the problem that the plants die after water supplement;

(4) the utility model discloses used solar cell to supply power, energy saving, green for the control unit of whole device.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic overall structure diagram of an indoor intelligent watering device for green plants;

FIG. 2 is a schematic cross-sectional structure diagram of an indoor intelligent watering device for green plants;

FIG. 3 is a schematic top view of an indoor intelligent watering device for green plants;

FIG. 4 is a schematic diagram of a drain pipe structure of the indoor intelligent watering device for green plants;

fig. 5 is a schematic structural diagram of a drain hole of the indoor green plant intelligent watering device.

In the drawings, the components represented by the respective reference numerals are listed below:

1-chassis, 2-telescopic supporting legs, 3-water storage chamber, 4-electromagnetic valve, 5-water filling port, 6-water discharging hole, 7-water discharging pipe, 8-solar panel, 9-device cavity, 10-storage battery, 11-controller, 12-camera, 13-soil humidity sensor and 14-flow sensor.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1-5, an indoor intelligent watering device for green plants comprises a support part, a water storage part, a control part, a power supply part, a monitoring part and a drain pipe; the support part comprises a chassis 1 and four telescopic legs 2 with adjustable heights, and one ends of the four telescopic legs 2 are welded on the chassis 1; the support part is welded at the bottom of the water storage chamber 3 through the other ends of the four telescopic supporting legs 2; the water storage part comprises a water storage chamber 3, a water discharge hole 6, an electromagnetic valve 4, a water injection port 5 and a device cavity 9; the water storage chamber 3 is a cylindrical cavity, the water discharge hole 6 is formed in the bottom of the water storage chamber, the electromagnetic valve 4 is installed on the water discharge hole 6 to control water circulation, and the semicircular water injection port 5 is formed in the top of the water storage chamber 3 to facilitate water injection into the water storage chamber 3; the device cavity 9 is positioned at one side in the water storage chamber 3 and is a semicircular hollow cavity; the control part comprises a controller 11, a single chip microcomputer, a WIFI module, a cloud server and a mobile phone APP control module; the controller is positioned in the device cavity 9, and the singlechip and the WiFi module are integrated on the controller; the power supply part comprises a solar panel 8, a storage battery 10 and a power line; the solar cell panel 8 is positioned at the top of the water storage chamber 3, and the storage battery 10 is positioned in the device cavity 9; the monitoring part comprises a camera 12, a flow sensor 14 and a soil humidity sensor 13; the camera 12 is arranged on a circular ring outside the water storage chamber 3, the flow sensor 14 is arranged in the drain hole 6, and the soil humidity sensor 13 is arranged at the tail end of the drain pipe 7. The camera 13, the flow sensor 14 and the soil humidity sensor 13 are all provided with lines to be connected with the controller 11 and the storage battery 10.

Example 1

The utility model discloses during the use camera 13 can shoot the plant photo and upload to the cloud end server, and the cloud end server is according to the green article of planting in the photo identification photo of existing photo identification technology, through retrieving the plant data database in the cloud end server after the discernment is accomplished, feeds back the singlechip in controller 11 to the cultivation habit data of watering of this plant, and soil moisture sensor 13 detects the humidity in the soil and sends data to the singlechip simultaneously, sets for watering volume and watering cycle according to soil moisture and each green planting habit data by the singlechip; if watering is needed, the single chip microcomputer outputs a corresponding control signal to the electromagnetic valve 4 to control the opening of the valve, water in the water storage chamber 3 flows to corresponding green plant soil through the water discharge pipe 7, meanwhile, the flow sensor 14 in the water discharge hole 6 monitors the flowing water amount and feeds back data to the single chip microcomputer in real time, and when the flow reaches the required value of corresponding green plants, the single chip microcomputer outputs a control signal to the electromagnetic valve 4 to control the closing of the valve. When need water but flow sensor 14 does not monitor the flow value, show that the water storage in reservoir chamber 3 has been used up, the monolithic chance passes through the WIFI module the high in the clouds server with cell-phone APP control module carries out data connection, sends the moisturizing to the user and reminds.

Example 2

Each apopore of user's accessible APP control, the frequency of watering, the water yield and the time of watering of self-defining each basin green plant. During the use, the user can carry out data connection through the WIFI module through the app of cell-phone end and the device that waters, the growth situation of every basin plant is observed to camera 12 on the device that the operation waters, if it is not good to send out the plant growth condition, alright select the plant by oneself on app to set up the frequency of watering, the amount of water and the time of watering, app can give the singlechip in the device that waters through the WIFI module to the data transmission that sets for, the singlechip no longer waters according to the sensor control in the device that waters, but realizes the frequency of watering, the amount of water of watering and the change of the time of watering through opening and closing control solenoid valve 4 according to the data that the user set for by oneself.

The utility model discloses a many drain lines set up and can water simultaneously to green planting of basin, solved most of intelligence on the market and watered the puzzlement that a basin green plant was watered, and through the picture recognition technology to present ten minutes popularization and maturity, high in the clouds service technology, network communication technology's integration, we can have corresponding adjustment to the green volume of watering of planting of every basin and the cycle of watering, can combine the watering that the corresponding green type habit of planting carries out different cycles and water yield according to soil moisture, still can remind the user moisturizing through cell-phone end APP simultaneously when the storage water tank does not have water, just the utility model discloses solar cell has still been used, economize on electricity environmental protection.

In the description herein, references to the description of "one embodiment," "an example," "a specific example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the present invention disclosed above are intended only to help illustrate the present invention. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, to thereby enable others skilled in the art to best understand the invention for and utilize the invention. The present invention is limited only by the claims and their full scope and equivalents.

Claims (4)

1. The utility model provides an indoor green plant intelligence device that waters which characterized in that: the indoor intelligent watering device for green plants comprises a support part, a water storage part, a control part, a power supply part, a monitoring part and a drain pipe, wherein the bottom end of the water storage part is connected with the support part, the upper end of the water storage part is connected with the power supply part, the control part and the detection part are arranged in the water storage part, and the drain pipe is arranged outside the water storage part;

the support part comprises a chassis and four telescopic supporting legs with adjustable heights, and one ends of the four telescopic supporting legs are welded on the chassis; the supporting seat part is welded at the bottom of the water storage part through the other ends of the four telescopic supporting legs;

the water storage part comprises a water storage chamber, a water discharge hole, an electromagnetic valve and a water injection port device cavity; the water storage chamber is a cylindrical cavity, the water discharge hole is formed in the bottom of the water storage chamber, the electromagnetic valve is installed on the water discharge hole to control water circulation, and the top of the water storage chamber is provided with a semicircular water injection port; the device cavity is positioned on one side in the water storage chamber and is a semicircular hollow cavity, and a control part is arranged in the device cavity;

the control part comprises a controller, a single chip microcomputer, a WIFI module, a cloud server and a mobile phone APP control module; the controller is positioned in the device cavity, and the singlechip and the WiFi module are integrated on the controller; the WIFI module is in bidirectional connection with the single chip microcomputer, and is in communication connection with the mobile phone APP control module through the cloud server;

the power supply part comprises a solar cell panel, a storage battery and a power line; the solar cell panel is positioned at the top of the water storage chamber, the storage battery is positioned in the device cavity, and the storage battery is provided with a power line;

the monitoring part comprises a camera, a flow sensor and a soil humidity sensor; the camera is arranged on a circular ring outside the water storage chamber, the flow monitoring sensor is arranged in the drainage hole, and the soil humidity sensor is arranged at the tail end of the drainage pipe;

the camera, the flow sensor and the soil humidity sensor are all provided with lines to be connected with the single chip microcomputer and the storage battery.

2. The indoor intelligent green plant watering device of claim 1, wherein: the number of the drain holes is 16, and the drain holes are annularly arranged on the inner wall of the bottom of the water storage chamber at equal intervals; each drain hole is provided with an independent electromagnetic valve, and each drain hole is internally provided with a flow monitoring sensor.

3. The indoor intelligent green plant watering device of claim 1, wherein: the number of the drain pipes is 16, and each tail end is provided with a soil humidity sensor.

4. The indoor intelligent green plant watering device of claim 1, wherein: the single chip microcomputer adopts an STM32 series microcontroller STM32F103VET6 based on an ARMCortex-M3 inner core.

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