CN215530282U - Basin support of intelligent flowerpot - Google Patents

Abstract

The utility model discloses a pot support of an intelligent flowerpot, which has the technical scheme that the pot support comprises a pot support body, a water storage bag, a main control device and an automatic watering device, wherein the pot support body comprises a shell, an upper shell and a base; the automatic watering device comprises a first water conveying pipeline, an electromagnetic valve and a second water conveying pipeline; the main control device comprises a main control module, an execution module, a power supply module and a remote communication module. The intelligent pot support aims to solve the problems of convenience, attractiveness and intelligence of indoor green plant unmanned watering maintenance, an additional water tank and a water pipe do not need to be installed, redundant electric wires do not need to be connected for power supply, meanwhile, the intelligent pot support can be connected with a background AI artificial intelligent server, the AI artificial intelligent server intelligently analyzes and decides watering time and watering quantity suitable for different green plants through a model constructed by one or more sensors, and the low-power-consumption electromagnetic switches of the intelligent pot support are respectively controlled for irrigation, so that the unmanned intelligent maintenance is achieved.

Description

Basin support of intelligent flowerpot

Technical Field

The utility model relates to household articles, in particular to a pot support of an intelligent flowerpot.

Background

The flower pot and the utensil for planting flowers are in the shape of an inverted round table or an inverted truncated pyramid with a large opening and a small bottom. In the life of people, pot plants are indispensable articles for life, but the pot plants are often forgotten to be watered, or sometimes the pot plants cannot be watered after leaving home for a period of time, so that green plants in the pot plants die.

The prior art scheme can be divided into three categories according to functions, one category is slow infiltration soil moisture keeping without electronic equipment, the other category is automatic irrigation with partial electronic equipment for controlling timing and quantitative watering, and the other category is self-independent system. The automatic watering scheme of an independent system is characterized in that a small automatic watering control system is formed by a flowerpot, a water tank, a water pipe, a water pump, a sensor and a controller, and the automatic watering control system is supported by an external power supply and certain parameter values set by the controller.

In the prior art, a small control system is built together with a flowerpot, watering is controlled through a water tank, a water pipe, a sensor, a water pump and a central controller, a power supply is required to be connected, and each set of system needs to set a fixed watering threshold value by self. The disadvantages are that water pipes and electric wires are needed, and an additional place is needed to place a water tank and use a water pump to pump water for irrigation. This can make placement of green plants inconvenient, aesthetically undesirable, and irrigation without intelligence to determine when it is time to actually water, and how much water should be poured.

Disclosure of Invention

The intelligent pot support aims to solve the problems of convenience, attractiveness and intelligence of indoor green plant unmanned watering maintenance, an additional water tank does not need to be installed, a water pipe does not need to be laid, redundant electric wires do not need to be connected for power supply, meanwhile, the intelligent pot support can be connected with a background AI artificial intelligent server, the AI artificial intelligent server intelligently analyzes and decides watering time and watering quantity suitable for different green plants through a model constructed by one or more sensors, and the low-power-consumption electromagnetic switches of the intelligent pot support are respectively controlled for irrigation, so that the unmanned intelligent maintenance is achieved.

In order to achieve the purpose, the utility model provides the following technical scheme: a pot support of an intelligent flowerpot comprises a pot support body, a water storage bag arranged in the pot support body, a main control device and an automatic watering device matched with the water storage bag, wherein the pot support body comprises a shell, an upper shell movably matched with an upper opening of the shell and a base arranged at a lower opening of the shell; the automatic watering device comprises a first water conveying pipeline, an electromagnetic valve and a second water conveying pipeline which are sequentially connected to the water outlet end of the water storage bag; the main control device comprises a main control module, an execution module, a power supply module and a remote communication module, wherein the main control module is arranged on the base and is used for signal data transmission and processing of automatic watering and weight detection; the input end of the execution module is connected with the output end of the main control module, and the output end of the execution module is connected with the input end of the electromagnetic valve and used for controlling the opening and closing of the electromagnetic valve; the power supply module outputs power supply power to each module and the electromagnetic valve and sends a power supply output power signal to the main control module; and the remote communication module is used for connecting the client terminal to carry out bidirectional communication control.

Preferably, the base is provided with a weight sensor connected to the input end of the main control module.

Preferably, a guide pressure plate is arranged between the upper end face of the upper shell and the water storage bag, and the guide pressure plate is matched with the upper end face of the upper shell in a threaded mode.

Preferably, the upper end surface of the upper shell is provided with a water leakage hole, the inner wall of the shell matched with the water leakage hole is provided with an inner water tank and a plurality of water guide holes matched with the inner water tank, and the outer surface of the shell is provided with an evaporation tank positioned at the lower end of the water guide hole.

Preferably, the inner water tank is provided with a monitoring electrode module connected with the input end of the main control module, an overflow signal of the monitoring inner water tank is transmitted to the main control module, and the main control module receives the overflow signal and then transmits a closing signal to the execution module.

Preferably, the main control device comprises a processing server, a cloud data system and a learning analysis module, the processing server receives the on-off information of the electromagnetic valve transmitted by the execution module, the on-off information received corresponds to real-time, data information of watering time is generated and transmitted to the cloud data system, the cloud data system generates a plurality of data information into modeling data, the modeling data are transmitted to the learning analysis module, the learning analysis module performs learning analysis on the received modeling data, a watering time instruction is generated, the watering time instruction is transmitted to the main control module, and the main control module starts and stops the execution module through the watering time instruction.

Preferably, the cloud data system is provided with a large database module, the cloud data system is provided with a soil humidity monitoring module in a matching mode, a data model which is authenticated in practice is stored in the large database module, the soil humidity monitoring module transmits soil humidity information monitored in real time to the cloud data system, the cloud data system generates modeling data from received soil humidity data and water shortage data in the large database, the modeling data is transmitted to the learning analysis module, and the learning analysis module compares the received soil humidity monitoring data with the water shortage data in the large database module to generate a watering instruction and transmits the watering instruction to the main control module.

Preferably, the cloud data system is provided with a learning supplement system, the cloud data system is provided with a green plant growth monitoring module in a matching mode, the green plant growth monitoring module transmits detected data to the learning supplement system, and the learning supplement system can train and analyze newly generated data to provide reference completion and transmit the reference completion to the large database module for data storage.

Preferably, the remote communication module is LoRa or WiFi.

Preferably, the first water pipeline comprises a first quick-plug connector arranged at the water outlet of the water storage bag, a second quick-plug connector arranged on the shell, a first water delivery pipe body connecting the first quick-plug connector and the water inlet of the control valve, and a second water delivery pipe body connecting the outlet water of the control valve and the second quick-plug connector; the second water pipeline comprises a spring water pipe connected with the outlet of the second quick-connection plug, a three-way quick-connection plug connected with the water outlet of the spring water pipe and two watering pipe bodies connected with the output end of the three-way quick-connection plug.

Compared with the prior art, the utility model has the beneficial effects that:

the intelligent pot support of flowerpot mainly solves the problem of green planting flowers as required automatic irrigation cultivated in a pot. The basin support has large water storage capacity, does not need a water pump to pump water for irrigation, utilizes the basin support structure to hide the water storage, utilizes the self weight of the flowerpot to load the flowerpot on the storage bag, extrudes the water in the bag, connects the water with the storage bag through a pipe, uses a pulse electromagnetic valve to open a pipeline, and utilizes the water pressure in the extruded belt to irrigate

The intelligent pot support aims to solve the problems of convenience, attractiveness and intelligence of indoor green plant unmanned watering maintenance, an extra water tank does not need to be installed, a water pipe does not need to be laid, redundant electric wires do not need to be connected for power supply, meanwhile, the intelligent pot support can be connected with a background AI artificial intelligent server, the AI artificial intelligent server intelligently analyzes and decides watering time and watering quantity suitable for different green plants through a model established by one or more sensors, and the low-power-consumption electromagnetic switches of the intelligent pot support are respectively controlled for irrigation, so that the unmanned intelligent maintenance is achieved.

The utility model has the advantages that the low-power-consumption electromagnetic valve controlled by the server is combined with the sensor, whether the green plants reach the state needing watering can be intelligently judged, the watering amount is determined, and the watering according to the required amount is realized. The existing scheme can not achieve the optimal purpose of watering green plants by either regularly and quantitatively watering or slowly seeping water.

Drawings

FIG. 1 is an overall perspective view of the present invention;

FIG. 2 is a side elevational view of the present invention;

FIG. 3 is an exploded perspective view of the present invention;

FIG. 4 is an exploded side view of the present invention;

FIG. 5 is a schematic block diagram of the system of the present invention;

in the figure: 1. a basin support body; 2. a water storage bag; 3. an automatic watering device; 4. a housing; 5. An upper housing; 6. a base; 7. an electromagnetic valve; 8. a weight sensor; 9. a master control device; 10. An inner water tank; 11. a guide pressure plate; 12. a first quick connector; 13. a water guide hole; 14. an evaporation tank; 15. a second quick connector; 16. a spring water pipe; 17. a three-way quick connector; 18. watering the pipe body; 19. a flower pot; 20. planting green; 21. self-adaptive basin clip.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1 to 5, the present invention provides a technical solution: a pot support of an intelligent flowerpot comprises a pot support body 1, a water storage bag 2 arranged in the pot support body 1, a main control device 9 and an automatic watering device 3 matched with the water storage bag 2, wherein the pot support body 1 comprises a shell 4, an upper shell 5 movably matched with an upper opening of the shell 4 and a base 6 arranged at a lower opening of the shell 4; the automatic watering device 3 comprises a first water delivery pipeline, an electromagnetic valve 7 and a second water delivery pipeline which are sequentially connected with the water outlet end of the water storage bag 2; the main control device 9 comprises a main control module, an execution module, a power supply module and a remote communication module which are arranged on the base 6, wherein the main control module is used for transmitting and processing automatic watering signal data; the input end of the execution module is connected with the output end of the main control module, and the output end of the execution module is connected with the input end of the electromagnetic valve 7 and used for controlling the opening and closing of the electromagnetic valve 7; the power supply module outputs power supply power to each module and the electromagnetic valve 7 and sends a power supply output power signal to the main control module; and the remote communication module is used for connecting the client terminal to carry out bidirectional communication control.

The remote communication module is LoRa or WiFi.

In the utility model, the intelligent pot support consists of a pot support body 1, a main control device 9, a replaceable water storage bag 2, an execution module and a power module, wherein the upper shell 5 is used for contacting the pot support with the bottom surface of a green plant 20 flowerpot, the upper shell 5 is designed to be a stepped inner ring, the intelligent pot support can adapt to and position flowerpots with different bottom diameters, and the output end of a second water pipeline is arranged at the upper opening of the flowerpot to be watered.

In the utility model, the main control device 9 adopts a LoRa or WiFi communication board as a main control, and a client terminal connected with the pot support can use a mobile phone, for example, an APP specially controlling the use of the pot support transmits preset data to the pot support through the APP, a main control module of the pot support receives the preset data, and the flowerpot is automatically watered through the preset data. After the flowerpot is placed at the upper end of the pot support, the APP on the mobile phone is wirelessly connected with the pot support through WiFi, presetting the watering amount and the watering interval time on the APP, transmitting the preset numerical value to a main control module of the basin support by the APP, processing and storing the preset numerical value by the main control module, the watering instruction, the watering quantity signal and the watering interval time signal are transmitted to the execution module, after the execution module receives the watering signal, the electromagnetic valve 7 is controlled to be opened, water in the water storage bag 2 flows out due to the gravity of the flowerpot, flows out from the second water pipeline and finally falls into the flowerpot for irrigation, the electromagnetic valve 7 is provided with a flow detection module, the output end of the flow detection module is connected with the execution module, when the execution module receives that the numerical value transmitted by the flow detection module is consistent with the watering quantity signal transmitted by the main control module, the execution module controls the electromagnetic valve 7 to be closed. When the second watering time is up, the actuating mechanism opens and closes the electromagnetic valve 7 again to realize the second watering, and the water storage bag 2 can be taken out for replacement or full filling for the next round of automatic watering because the upper shell 5 is movably connected with the shell 4 until the water in the water storage bag 2 is not enough to reach the watering amount.

And a weight sensor 8 connected to the input end of the main control module is arranged between the base 6 and the water storage bag 2.

In the utility model, the gravity sensor on the base 6 is positioned at the lower end of the water storage bag 2 and is used for collecting the total weight of the water storage bag 2, the upper shell 5 and the flowerpot and transmitting the detected weight data to the main control module, the weight data of the main control module is transmitted to a client terminal, such as an APP of a mobile phone, through the remote communication module, and the weight data is displayed on the APP. After watering at every turn, weight sensor 8 carries out the detection again, gives APP with new weight data transmission to carry out real-time supervision, judge the water yield surplus through the number difference that reduces, thereby the suggestion user carries out the change of water storage bag 2 or fills water.

A guide pressing plate 11 is arranged between the upper end face of the upper shell 5 and the water storage bag 2, and the guide pressing plate 11 is matched with the upper end face of the upper shell 5 in a threaded mode.

In the utility model, the guide pressure plate 11 is connected with the upper shell 5 through threads, and the distance between the pressure plate and the inner side of the upper shell 5 can be adjusted through the threads, so that the water storage bag 2 with different heights can be adapted.

The upper end surface of the upper shell 5 is provided with a water leakage hole, the inner wall of the shell 4 matched with the water leakage hole is provided with an inner water tank 10 and a plurality of water guide holes 13 matched with the inner water tank 10, and the outer surface of the shell 4 is provided with an evaporation tank 14 positioned at the lower end of the water guide holes 13.

In the utility model, in order to ensure the accuracy of the diversion, the diameter of the water storage bag 2 is smaller than that of the pressing plate body, the water leakage hole can be arranged on the upper end surface of the upper shell 5, and when the upper shell 5 is provided with a central threaded hole matched with the guide pressing plate 11, the water leakage hole can also be arranged on the central threaded hole and is used for conveying water which overflows from the flowerpot or is completely poured, the water is guided into the inner water tank 10 in the shell 4 through the surface of the guide pressing plate 11.

In the utility model, an evaporation groove 14 is arranged outside the shell 4, and redundant water overflows from the inner water groove 10 through the water guide hole 13 and then flows into the evaporation groove 14 through the radian outer wall of the shell 4, so that the redundant water is prevented from overflowing to the ground, and the drying stability of the basin support is also ensured.

The inner water tank 10 is provided with a monitoring electrode module connected with the input end of the main control module, an overflow signal for monitoring the inner water tank 10 is transmitted to the main control module, and the main control module receives the overflow signal and then transmits a closing signal to the execution module.

According to the utility model, the watering amount is limited according to the amount of water needed by the soil in the flowerpot without setting the watering amount through APP, so that an automatic intelligent watering effect is realized. 2 pairs of monitoring electrode modules are arranged in the inner water tank 10 and used for monitoring water overflowing after the flowerpot is watered, the water is used as a watering in-place signal, the electromagnetic valve 7 is closed in advance through the execution module, and watering is finished. Although can set up the water yield through client terminal, because factors such as ambient temperature can make soil different to the demand of water, still can appear the too much phenomenon of water yield, set up monitoring electrode module and monitor the water that overflows, the signal through monitoring electrode module comes closing of control solenoid valve 7. Put the flowerpot on the basin support body 1 when the user, after supporting body 1 wireless connection through customer's terminal and basin, only need set up the interval time of watering on APP this moment, APP will predetermine numerical value and send the host system of basin support to, host system handles and stores predetermineeing numerical value, will water the instruction and water the interval time and pass to the execution module, after the execution module received the signal, open solenoid valve 7 and water, when monitoring electrode module monitors interior basin 10 has the water that spills over, signal transmission who has water to spill over gives the execution module, execution module carries out closed control to solenoid valve 7. When the second irrigation time is reached, the actuating mechanism opens the electromagnetic valve 7 again to perform the second round of irrigation until the water in the water storage bag 2 is not enough for irrigation.

The main control device 9 comprises a processing server, a cloud data system and a learning analysis module, the processing server receives on-off information of the electromagnetic valve 7 transmitted by the execution module, the received on-off information corresponds to real-time, data information of watering time is generated, the data information is transmitted to the cloud data system, the cloud data system generates modeling data from a plurality of data information, the modeling data are transmitted to the learning analysis module, the learning analysis module performs learning analysis on the received modeling data, watering time instructions are generated, the watering time instructions are transmitted to the main control module, and the main control module starts and stops the execution module through the watering time instructions.

In the utility model, the detection electrode module can determine that the watering is saturated through the overflow of water, but the detection electrode module is closed under the condition that the water overflows, in order to improve the intelligence of the pot support, automatic learning optimization can be carried out through a learning system similar to an AI (artificial intelligence) through watering overflow information, and the watering quantity is enough and does not overflow after a plurality of times of watering. The utility model discloses a water time of watering is calculated to time of watering through multiunit, and water time transmits execution module, make execution module accomplish to open and close work to solenoid valve 7 by oneself, first several times, transmit the opening signal to execution module through host system earlier, detect electrode module transmits closed signal to execution module, execution module will once open and closed signal all transmits for processing server, processing server will receive opening and closing signal and real-time correspond, generate the data message of time of watering each time, will transmit data message for high in the clouds data system, high in the clouds data system packs the data signal of last several times, obtain the modeling data, transmit modeling data for the study analysis module again, the study analysis module calculates the time of watering of least easy overflow through multiunit's time of watering, and transmit the time of watering for execution module, let execution module accomplish to open and close work to solenoid valve 7 by oneself. Certainly, the water demand of soil is different due to the reason of environment temperature, the phenomenon of water overflow can also occur, at the moment, the detection electrode module transmits closed information to the execution module, the watering time before the execution module stops is set, new closed information is transmitted to the learning analysis module, the learning analysis module optimizes learning at the moment, new watering time is analyzed, a new watering time instruction is transmitted to the main control module, and the main control module opens and closes the execution module through the watering time instruction.

The high in the clouds data system is equipped with big database module, cooperates the high in the clouds data system is equipped with soil humidity monitoring module, the storage has the data model through practice authentication in the big database module, soil humidity monitoring module transmits real-time supervision's soil humidity information for high in the clouds data system, high in the clouds data system generates the modeling data with the lack of water data in received soil humidity data and the big database, gives the learning analysis module with the modeling data again, learning analysis module will receive soil humidity prison and lack of water data in the big database module and carry out the contrast and generate the instruction of watering and transmit for master control module.

In the utility model, in order to irrigate the pot support in a soil water shortage state, the irrigation can be stopped when the soil reaches a certain saturated adaptation point, the optimal living state of the green plants 20 is given, and the watering time and the watering amount of the green plants 20 are analyzed and decided through AI intelligence. Data model in big database module is the current data through manual input, for example, soil lack of water appointed value, the appointed value of the most suitable humidity of soil, green 20 respiratory data of planting etc, soil humidity monitoring module carries out real-time detection to the humidity of soil in the flowerpot, and transmit detected data for high in the clouds data system, high in the clouds data system will detect the soil lack of water appointed value in data and the big database and generate the modeling data and transmit for study analytic system, study analytic system learns the gap, generate the instruction of watering, and will water the instruction and transmit for execution module, realized under the state of soil in the flowerpot in lack of water, just water, the time that intelligent analysis needs to water.

The cloud data system is provided with a learning supplement system, the cloud data system is matched with a green plant 20 growth monitoring module, the green plant 20 growth monitoring module transmits detected data to the learning supplement system, and the learning supplement system can train and analyze newly generated data to provide reference completion and transmit the reference completion to a big database module for data storage.

In the utility model, the green plant 20 growth monitoring module is in the prior art, the growth state of the green plant 20 can be obtained according to the data of the respiration of the green plant 20 and the like, the growth states of different green plants 20 can be intelligently analyzed, the watering time and the watering amount of different green plants 20 can be determined, and the learning and supplementing system can update the large database module.

The first water pipeline comprises a first quick-plug connector 12 arranged at the water outlet of the water storage bag 2, a second quick-plug connector 15 arranged on the shell 4, a first water delivery pipe body connected with the first quick-plug connector and the water inlet of the electromagnetic valve 7, and a second water delivery pipe body connected with the outlet water of the electromagnetic valve 7 and the second quick-plug connector 15.

The second water pipeline comprises a spring water pipe 16 connected with the water outlet of the second quick-connection plug, a three-way quick-connection plug 17 connected with the water outlet of the spring water pipe 16 and two watering pipe bodies connected with the output end of the three-way quick-connection plug.

Through the technical scheme, the upper shell 5 provided with the guide pressure plate 11 is taken down from the upper opening of the shell 4, the water storage bag 2 is taken out, water is filled into the water storage bag 2 through the opening at the lower end, the filled water storage bag 2 is placed into the shell 4, the opening at the lower end is aligned with the first quick-plug connector 12, the upper shell 5 with the guide pressure plate 11 is placed at the upper end of the water storage bag 2, after the position of the guide pressure plate 11 is changed to the most suitable height, the flowerpot is placed on the upper end surface of the upper shell 5, the watering pipe body 18 is fixed on two side walls of the upper opening of the flowerpot through the self-adaptive pot clamp, finally the electromagnetic valve 7 is opened, and the guide pressure plate 11 exerts downward pressure on the water storage bag 2 due to the gravity of the flowerpot, so that the water in the water storage bag 2 flows out from the first quick-plug connector 12, the first water conveying pipe body, the second quick-plug connector 15, the second water conveying pipe body and the watering pipe body 18 in sequence, finally fall into the flowerpot.

The main control module comprises a processing server and a cloud data system, the input end of the processing service module is connected to the output end of the execution module, the processing server receives the on-off information of the electromagnetic valve 7 transmitted by the execution module, corresponds the received on-off information with the real-time, generates modeling data of watering time, and transmits the modeling data to the cloud data system.

The cloud data system comprises a big database and a learning supplement system, all model data which are subjected to practice certification are stored in the big database, and the learning supplement exercises can train and analyze newly generated model data to provide reference completion and transmit the reference completion to the big database for data storage.

In the utility model, in order to obtain the fixed watering time which does not overflow at last and can moisten the soil, because of the influence of the soil and the environment, the electromagnetic valve 7 is closed and the watering is stopped by monitoring the overflow condition of the electrode module in the first watering of the flowerpot placed on the pot support, the opening and closing information of the electromagnetic valve 7 in the first watering is transmitted to the processing server, the calculation and the automatic learning optimization are carried out by the cloud data system, and the watering time which does not overflow water can be obtained after a plurality of watering.

The first water conveying pipeline comprises a first quick-plug connector 12 arranged at the water outlet of the water storage bag 2, a second quick-plug connector 15 arranged on the shell 4, a first water conveying pipe body connecting the first quick-plug connector and the water inlet of the electromagnetic valve 7, and a second water conveying pipe body connecting the outlet water of the electromagnetic valve 7 and the second quick-plug connector 15; the second water pipeline comprises a spring water pipe 16 connected with the water outlet of the second quick-connection plug, a three-way quick-connection plug 17 connected with the water outlet of the spring water pipe 16 and two watering pipe bodies 18 connected with the output end of the three-way quick-connection plug.

In the utility model, the first quick-connect connector 12 and the second quick-connect connector 15 are used for supporting two water delivery pipe bodies, the two water delivery pipe bodies are arranged in the shell 4 and connected with the first quick-connect connector 12 and the second quick-connect connector 15, the spring water pipe 16 is arranged outside the shell 4 and connected with the second quick-connect connector and the watering pipe body 18, the watering pipe body 18 is arranged at the upper opening of the flowerpot, and the spring water pipe 16 can adapt to flowerpots with different heights.

In the utility model, the watering pipe body 18 is arranged at the opening at the upper end of the flowerpot, the watering pipe body 18 is an arc-shaped watering pipe body 18, the arc-shaped watering pipe body 18 is sleeved with a self-adaptive pot clamp 21, the self-adaptive pot clamp 21 is clamped on the upper edge wall of the flowerpot, the water outlet of the arc-shaped watering pipe body 18 is controlled to be aligned to the inside of the opening on the flowerpot, and the self-adaptive pot clamp can be suitable for flowerpots with different sizes, so that water can be accurately poured into the flowerpot. In order to ensure that the water on the two sides of the flowerpot is uniformly poured, 2 watering pipe bodies 18 are symmetrically arranged and are used for respectively watering the two sides of the flowerpot.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a basin of intelligence flowerpot holds in palm which characterized in that: the flowerpot support comprises a flowerpot support body (1), a water storage bag (2) arranged in the flowerpot support body (1), a main control device (9) and an automatic watering device (3) matched with the water storage bag (2), wherein the flowerpot support body (1) comprises a shell (4), an upper shell (5) movably matched with an upper opening of the shell (4) and a base (6) arranged at a lower opening of the shell (4); the automatic watering device (3) comprises a first water delivery pipeline, an electromagnetic valve (7) and a second water delivery pipeline which are sequentially connected with the water outlet end of the water storage bag (2); the main control device (9) comprises a main control module, an execution module, a power supply module and a remote communication module which are arranged on the base (6), and the main control module is used for signal data transmission and processing of automatic watering and weight detection; the input end of the execution module is connected with the output end of the main control module, and the output end of the execution module is connected with the input end of the electromagnetic valve (7) and used for controlling the opening and closing of the electromagnetic valve (7); the power supply module outputs power supply power to each module and the electromagnetic valve (7) and sends a power supply output power signal to the main control module; and the remote communication module is used for connecting the client terminal to carry out bidirectional communication control.

2. The pot support of intelligent flowerpot according to claim 1, characterized in that: and a weight sensor (8) connected to the input end of the main control module is arranged between the base (6) and the water storage bag (2).

3. The pot support of intelligent flowerpot according to claim 1, characterized in that: a guide pressing plate (11) is arranged between the upper end face of the upper shell (5) and the water storage bag (2), and the guide pressing plate (11) is matched with the upper end face of the upper shell (5) in a threaded mode.

4. The pot support of intelligent flowerpot according to claim 1, characterized in that: the upper end surface of the upper shell (5) is provided with a water leakage hole, the inner wall of the shell (4) matched with the water leakage hole is provided with an inner water tank (10) and a plurality of water guide holes (13) matched with the inner water tank (10), and the outer surface of the shell (4) is provided with an evaporation tank (14) positioned at the lower end of the water guide holes (13).

5. The pot support of intelligent flowerpot according to claim 1, characterized in that: the remote communication module is LoRa or WiFi.

6. The pot support of intelligent flowerpot according to claim 1, characterized in that: the first water conveying pipeline comprises a first quick-plug connector (12) arranged at the water outlet of the water storage bag (2), a second quick-plug connector (15) arranged on the shell (4), a first water conveying pipe body connecting the first quick-plug connector and the water inlet of the control valve, and a second water conveying pipe body connecting the water outlet of the control valve and the second quick-plug connector (15); the second water pipeline comprises a spring water pipe (16) connected with the water outlet of the second quick-connection plug, a three-way quick-connection plug (17) connected with the water outlet of the spring water pipe (16) and two watering pipe bodies (18) connected with the output end of the three-way quick-connection plug.

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