Self-adapting stable flowerpot
By using an adaptive stabilization mechanism and an automatic watering mechanism, the problems of flower pots being prone to tipping over and having poor shock absorption have been solved, enabling real-time stability adjustment and precise watering of flower pots, adapting to the needs of diverse placement and unattended scenarios.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- QUANZHOU LONGXIN ARTS & CRAFTS CO LTD
- Filing Date
- 2025-10-04
- Publication Date
- 2026-07-07
AI Technical Summary
Traditional flowerpots are prone to tipping over in locations susceptible to wind or impact. They lack real-time monitoring and mechanisms for actively adjusting the center of gravity, thus failing to effectively protect plants. Furthermore, their shock absorption is inadequate, making them unsuitable for diverse placement needs.
The device employs an adaptive stabilization mechanism that uses a high-precision triaxial gravity sensor to detect the tilt angle and center of gravity shift of the flowerpot in real time. The position of the counterweight is adjusted through an electrically controlled telescopic column and a sliding seat, and vibration is absorbed by a high-elasticity silicone shock-absorbing pad, thus achieving real-time active adjustment of the flowerpot and enhancing its stability. At the same time, the automatic watering mechanism achieves precise watering through a liquid level sensor and a water pump, eliminating the need for frequent manual operation.
It enables real-time stability adjustment of flower pots, preventing tipping and reducing vibration damage, ensuring the stability and safety of the plant growth environment, reducing the need for manual operation, and adapting to diverse placement scenarios.
Smart Images

Figure CN224460729U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of flower pot technology, specifically to an adaptive and stable flower pot. Background Technology
[0002] In current home and gardening settings, traditional flower pots have significant stability defects: when placed on balconies, windowsills, or other locations susceptible to wind or collisions, they are prone to tipping over, causing damage to the plant and spilling soil. This risk is even higher for large or tall plants. Some flower pots with fixing devices rely on external structures such as walls or railings for installation, limiting their applicability and making it difficult to meet diverse placement needs. Therefore, there is an urgent need for a dynamic, adaptable, portable, and stable self-adaptive solution that does not require external fixing.
[0003] Existing flowerpots lack a mechanism for real-time monitoring and active adjustment of the center of gravity. When subjected to external impact or placed on an uneven surface, they are prone to tilting or even tipping over. They cannot quickly correct the tilt and cannot effectively protect the plants inside the flowerpot. At the same time, their shock absorption effect is poor, and they cannot effectively absorb external vibrations. Vibrations can easily damage the plants inside the flowerpot. They may also cause the flowerpot to rub directly against the surface, causing damage to the surface of the flowerpot. Utility Model Content
[0004] The purpose of this invention is to provide an adaptive and stable flowerpot to solve the problems mentioned in the background art.
[0005] To achieve the above objectives, the present invention provides the following technical solution: an adaptive stabilizing flowerpot, comprising a flowerpot, wherein an adaptive stabilizing mechanism is provided on the surface of the flowerpot, and an automatic watering mechanism is provided on the surface of the flowerpot;
[0006] The adaptive stabilization mechanism includes a bottom mounting groove fixedly connected to the center of the flowerpot's bottom. A limit cover is installed at the bottom of the bottom mounting groove. A high-precision triaxial gravity sensor is installed inside the bottom mounting groove. Sliding rails are fixedly connected to each of the four corners of the flowerpot's bottom. Fixed plates are fixedly connected to the four corners of the inner end of the flowerpot's bottom. Sliding seats are slidably connected to the surface of the sliding rails. A connecting seat is installed inside the sliding seat. An electrically controlled telescopic column is installed between the connecting seat and the fixed plate. A counterweight is provided on the top of the sliding seat. High-elasticity silicone shock-absorbing pads are installed at the four corners of the flowerpot's bottom. The bottom of the high-elasticity silicone shock-absorbing pads has anti-slip textures. The high-precision triaxial gravity sensor at the bottom of the flowerpot can detect the flowerpot's tilt angle and center of gravity shift in real time and feed the data back to the control terminal. When a tilted flowerpot is detected, the control unit drives the electrically controlled telescopic column to extend and retract, causing the sliding seat to move along the sliding track, adjusting the position of the counterweight, adjusting the center of gravity of the flowerpot, quickly correcting the tilt, and preventing the flowerpot from tipping over. The high-elasticity silicone shock-absorbing pads at the four corners of the bottom of the flowerpot are the core shock-absorbing components. The honeycomb air chambers inside can effectively absorb external vibrations, reducing the impact of vibrations on the overall stability of the flowerpot, while preventing damage caused by direct friction between the flowerpot and the placement surface. The counterweight is set in four groups and is made of high-density cast iron. The weight can be flexibly adjusted according to the weight of the plant inside the flowerpot, ensuring that different types of flowerpots can obtain appropriate counterweight support, avoiding poor stability due to insufficient counterweight. The adaptive stabilization mechanism can realize real-time active adjustment, accurately maintain balance, and enhance the bottom grip and shock absorption capabilities.
[0007] Preferably, the sliding seat is designed as a detachable structure, and the end of the electrically controlled telescopic column away from the fixed plate is installed inside the connecting seat.
[0008] Preferably, the counterweight is provided in four sets and is made of high-density cast iron, and its weight can be adjusted according to the size of the flowerpot.
[0009] Preferably, the high-elasticity silicone shock-absorbing pad is provided in four sets, and has a honeycomb-shaped air cavity inside.
[0010] Preferably, the automatic watering mechanism includes a small water tank installed on the surface of the flowerpot. A water supply pipe is fixedly connected to the top of the small water tank, and a water pump is installed on the surface of the water supply pipe. A nozzle is installed at one end of the water supply pipe, and a liquid level sensor is installed on the surface of the small water tank. The small water tank can store a certain amount of water in advance. When watering is needed, the water pump starts, delivering the water in the tank to the nozzle through the water supply pipe. The nozzle then sprays the water evenly onto the plants in the flowerpot, eliminating the need for frequent manual operation. This is especially suitable for situations where plants are unattended when the owner is away. By controlling the start-up time of the water pump, the water level can be precisely controlled for each watering. The automatic watering mechanism avoids the problems of overwatering leading to root rot or underwatering causing drought due to lack of experience during manual watering, ensuring a stable growing environment for plants. A liquid level sensor extends into the water tank to monitor the remaining water level in real time. When the water level falls below a preset threshold, it issues a timely reminder to prevent the plants from drying out due to insufficient water. Conversely, when there is too much water, the sensor provides feedback to prevent further watering and overflow, enhancing the safety and reliability of the watering process. The automatic watering mechanism enables automated watering, saving time and effort while providing precise water measurement. Real-time water level monitoring during use prevents both water shortage and overflow.
[0011] Preferably, the nozzle is installed at the end of the water supply pipe away from the small water tank, and the liquid level sensor detection end is located inside the small water tank.
[0012] Compared with the prior art, this utility model provides an adaptive and stable flowerpot with the following beneficial effects:
[0013] This adaptive stabilizing flowerpot features an adaptive stabilization mechanism. A high-precision triaxial gravity sensor at the bottom of the pot can detect the pot's tilt angle and center of gravity shift in real time, feeding the data back to the control unit. When tilting is detected, the control unit drives the electrically controlled telescopic column to extend and retract, moving the sliding seat along the sliding track to adjust the position of the counterweight and the center of gravity of the pot, quickly correcting the tilt and preventing the pot from tipping over. The high-elasticity silicone shock-absorbing pads at the four corners of the pot's bottom are the core shock-absorbing components. Their internal honeycomb-shaped air chambers effectively absorb external vibrations, reducing the impact of vibrations on the overall stability of the pot and preventing damage caused by direct friction between the pot and the surface. The counterweight is set in four groups and is made of high-density cast iron. The weight can be flexibly adjusted according to the weight of the plants inside the pot, ensuring that different types of pots receive appropriate counterweight support and avoiding poor stability due to insufficient counterweight. The adaptive stabilization mechanism can achieve real-time active adjustment, accurately maintain balance, and enhance the bottom grip and shock absorption capabilities.
[0014] This adaptive stabilizing flowerpot features an automatic watering mechanism. A small water tank can store a certain amount of water in advance. When watering is needed, the water pump starts, delivering water from the tank to the nozzles via a water pipe. The nozzles then spray the water evenly onto the plants in the pot, eliminating the need for frequent manual operation. This is especially suitable for situations where plants are unattended when you are away. By controlling the pump's start time, the amount of water given per watering can be precisely controlled, avoiding problems like overwatering leading to root rot or underwatering causing drought due to lack of experience. This ensures a stable growing environment for the plants. A liquid level sensor extends into the water tank to monitor the remaining water level in real time. When the water level falls below a preset threshold, it issues a timely reminder to prevent the plants from drying out. Conversely, if there is too much water, the sensor also provides feedback to prevent overfilling and overflow, enhancing the safety and reliability of the watering process. The automatic watering mechanism enables automated watering, saving time and effort while providing precise water distribution. Real-time water level monitoring during use prevents both water shortage and overflow. Attached Figure Description
[0015] To more clearly illustrate the technical solutions in the embodiments of this utility model, the drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0016] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0017] Figure 2 This is a schematic diagram of the bottom of the structure of this utility model;
[0018] Figure 3 This is a schematic diagram of the adaptive stabilization mechanism of this utility model.
[0019] Figure 4 This is a schematic diagram of the sliding track structure of this utility model.
[0020] In the diagram: 1. Flowerpot; 2. Adaptive stabilization mechanism; 21. Bottom mounting groove; 22. Limiting cover; 23. High-precision triaxial gravity sensor; 24. Sliding rail; 25. Fixing plate; 26. Sliding seat; 27. Connecting seat; 28. Electrically controlled telescopic column; 29. Counterweight; 201. High-elasticity silicone shock-absorbing pad; 202. Anti-slip texture; 3. Automatic watering mechanism; 31. Small water tank; 32. Water supply pipe; 33. Water pump; 34. Sprinkler head; 35. Liquid level sensor. Detailed Implementation
[0021] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0022] In this utility model, unless otherwise explicitly specified and limited, the terms "installation," "connection," "joining," and "fixing," etc., should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral part; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; they can refer to the internal communication of two components or the interaction between two components. Those skilled in the art can understand the specific meaning of the above terms in this utility model according to the specific circumstances.
[0023] This utility model provides the following technical solution: Example 1
[0024] Please see Figure 1-4 An adaptive stabilizing flowerpot includes a flowerpot 1, an adaptive stabilizing mechanism 2 on the surface of the flowerpot 1, and an automatic watering mechanism 3 on the surface of the flowerpot 1.
[0025] The adaptive stabilizing mechanism 2 includes a bottom mounting groove 21, which is fixedly connected to the center of the bottom of the flowerpot 1. A limit cover 22 is installed at the bottom of the bottom mounting groove 21. A high-precision triaxial gravity sensor 23 is installed inside the bottom mounting groove 21. Sliding rails 24 are fixedly connected to the four corners of the bottom of the flowerpot 1. Fixing plates 25 are fixedly connected to the four corners of the inner end of the bottom of the flowerpot 1. Sliding seats 26 are slidably connected to the surface of the sliding rails 24. A connecting seat 27 is installed at the inner end of the sliding seat 26. An electrically controlled telescopic column 28 is installed between the connecting seat 27 and the fixing plate 25. A counterweight 29 is set on the top of the sliding seat 26. High-elasticity silicone shock-absorbing pads 201 are installed at the four corners of the bottom of the flowerpot 1. The bottom of the high-elasticity silicone shock-absorbing pads 201 is provided with anti-slip texture 202. The high-precision triaxial gravity sensor 23 at the bottom of the flowerpot 1 can detect the tilt angle and center of gravity shift of the flowerpot 1 in real time and feed the data back to the control terminal. When the tilt of the flowerpot is detected, the control terminal drives the electric telescopic column 28 to extend and retract, which drives the sliding seat 26 to move along the sliding track 24, adjusts the position of the counterweight 29, adjusts the center of gravity position of the flowerpot 1, quickly corrects the tilt state, and prevents the flowerpot 1 from tipping over. The high-elasticity silicone shock-absorbing pads 201 at the four corners of the bottom of the flowerpot 1... As the core shock-absorbing component, its internal honeycomb air chamber can effectively absorb external vibrations, reduce the impact of vibrations on the overall stability of the flowerpot 1, and at the same time avoid damage caused by direct friction between the flowerpot 1 and the placement surface. The counterweight 29 is set with four groups and is made of high-density cast iron. The weight can be flexibly adjusted according to the size of the flowerpot 1 and the weight of the plant inside, ensuring that different types of flowerpots 1 can obtain appropriate counterweight support and avoid poor stability due to insufficient counterweight. The adaptive stabilization mechanism 2 can realize real-time active adjustment, accurately maintain balance, and enhance the bottom grip and shock absorption capacity. The high-precision triaxial gravity sensor 23 uses the model MMA8451.
[0026] The sliding seat 26 is designed as a detachable structure, and the end of the electrically controlled telescopic column 28 away from the fixed plate 25 is installed inside the connecting seat 27;
[0027] The counterweight 29 has four sets and is made of high-density cast iron. The weight can be adjusted according to the size of the flowerpot 1.
[0028] The high-elasticity silicone shock-absorbing pad 201 has four sets and a honeycomb-shaped air cavity inside. Example 2
[0029] Please see Figure 1-4Furthermore, based on Embodiment 1, the automatic watering mechanism 3 includes a small water tank 31, which is installed on the surface of the flowerpot 1. A water supply pipe 32 is fixedly connected to the top of the small water tank 31, and a water pump 33 is installed on the surface of the water supply pipe 32. A nozzle 34 is installed at one end of the water supply pipe 32, and a liquid level sensor 35 is installed on the surface of the small water tank 31. The small water tank 31 can store a certain amount of water in advance. When watering is needed, the water pump 33 starts, and the water in the tank is transported to the nozzle 34 through the water supply pipe 32. The nozzle 34 then sprays the water evenly onto the plants in the flowerpot. This eliminates the need for frequent manual operation and is especially suitable for situations where plants are left unattended when the plant is away from home. By controlling the start-up time of the water pump 33, precise watering can be achieved. To control the amount of water to be watered at one time, this system avoids the problems of overwatering and root rot or underwatering and drought caused by insufficient watering during manual watering due to lack of experience. It ensures a stable growing environment for plants. The liquid level sensor 35 extends into the water tank and can monitor the remaining water level in real time. When the water level is lower than the preset threshold, it can issue an alert in time to prevent the plants from drying out due to lack of water. When there is too much water, the sensor can also provide feedback to prevent the addition of water and overflow, thus improving the safety and reliability of the watering process. The automatic watering mechanism 3 enables automated watering, which saves time and effort and provides accurate water volume. The liquid level sensor 35 is model WKC1204-NP-FL.
[0030] The nozzle 34 is installed at the end of the water supply pipe 32 away from the small water tank 31, and the detection end of the liquid level sensor 35 is located inside the small water tank 31.
[0031] In actual operation, when this device is used, the components are installed on the surface of the flowerpot 1 in an orderly manner. During use, the high-precision triaxial gravity sensor 23 at the bottom of the flowerpot 1 can detect the tilt angle and center of gravity shift of the flowerpot 1 in real time and feed the data back to the control terminal. When the tilt of the flowerpot is detected, the control terminal drives the electric telescopic column 28 to extend and retract, which drives the sliding seat 26 to move along the sliding track 24, adjusts the position of the counterweight 29, adjusts the center of gravity of the flowerpot 1, and quickly corrects the tilt state to prevent the flowerpot 1 from tipping over. The high-elasticity silicone shock-absorbing pads 201 at the four corners of the bottom of the flowerpot 1 are the core shock-absorbing components. The honeycomb air chambers inside can effectively absorb external vibrations, reduce the impact of vibrations on the overall stability of the flowerpot 1, and at the same time prevent the flowerpot 1 from being damaged by direct friction with the placement surface. It is set to four groups and made of high-density cast iron. The weight can be flexibly adjusted according to the weight of the plant inside the flowerpot 1, ensuring that different types of flowerpot 1 can obtain appropriate counterweight support, avoiding poor stability due to insufficient counterweight. The adaptive stabilization mechanism 2 can achieve real-time active adjustment, accurately maintain balance, and enhance bottom grip and shock absorption.
[0032] The small water tank 31 can store a certain amount of water in advance. When watering is needed, the water pump 33 starts, and the water in the tank is delivered to the nozzle 34 through the water pipe 32. The nozzle 34 sprays the water evenly onto the plants in the flowerpot, eliminating the need for frequent manual operation. This is especially suitable for situations where plants are left unattended when you are away. By controlling the start time of the water pump 33, the amount of water for each watering can be precisely controlled, avoiding problems such as overwatering and root rot or underwatering and drought caused by insufficient experience when watering manually. This ensures a stable growing environment for the plants. The liquid level sensor 35 extends into the water tank and can monitor the remaining water in the tank in real time. When the water level is lower than the preset threshold, it can issue a timely reminder to prevent the plants from running out of water due to water shortage. When there is too much water, the sensor can also provide feedback to prevent further watering and overflow, improving the safety and reliability of the watering process. The automatic watering mechanism 3 enables automated watering, saving time and effort while providing accurate water volume. The water level is monitored in real time during use to prevent water shortage or overflow.
[0033] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such a process, method, article, or apparatus. Without further limitations, an element defined by the phrase "comprising one..." does not exclude the presence of other identical elements in the process, method, article, or apparatus that includes said element.
Claims
1. An adaptive stabilizing flowerpot, comprising a flowerpot (1), characterized in that: The surface of the flowerpot (1) is provided with an adaptive stabilization mechanism (2), and the surface of the flowerpot (1) is provided with an automatic watering mechanism (3). The adaptive stabilization mechanism (2) includes a bottom mounting groove (21), which is fixedly connected to the center of the bottom of the flowerpot (1). A limit cover (22) is installed at the bottom of the bottom mounting groove (21). A high-precision triaxial gravity sensor (23) is installed inside the bottom mounting groove (21). Sliding rails (24) are fixedly connected to the four corners of the bottom of the flowerpot (1). Fixed plates (25) are fixedly connected to the four corners of the inner end of the bottom of the flowerpot (1). A sliding seat (26) is slidably connected to the surface of the sliding rail (24). A connecting seat (27) is installed at the inner end of the sliding seat (26). An electrically controlled telescopic column (28) is installed between the connecting seat (27) and the fixed plate (25). A counterweight (29) is provided on the top of the sliding seat (26). High-elasticity silicone shock-absorbing pads (201) are installed at the four corners of the bottom of the flowerpot (1). Anti-slip textures (202) are provided at the bottom of the high-elasticity silicone shock-absorbing pads (201).
2. The adaptive stabilizing flowerpot according to claim 1, characterized in that: The sliding seat (26) is designed to be detachable, and the end of the electrically controlled telescopic column (28) away from the fixed plate (25) is installed inside the connecting seat (27).
3. The adaptive stabilizing flowerpot according to claim 1, characterized in that: The counterweight (29) is provided in four sets and is made of high-density cast iron. Its weight can be adjusted according to the specifications of the flowerpot (1).
4. The adaptive stabilizing flowerpot according to claim 1, characterized in that: The high-elasticity silicone shock-absorbing pad (201) is provided in four sets and has a honeycomb-shaped air cavity inside.
5. The adaptive stabilizing flowerpot according to claim 1, characterized in that: The automatic watering mechanism (3) includes a small water tank (31), which is installed on the surface of the flowerpot (1). A water supply pipe (32) is fixedly connected to the top of the small water tank (31), and a water pump (33) is installed on the surface of the water supply pipe (32). A nozzle (34) is installed at one end of the water supply pipe (32), and a liquid level sensor (35) is installed on the surface of the small water tank (31).
6. The adaptive stabilizing flowerpot according to claim 5, characterized in that: The nozzle (34) is installed at the end of the water supply pipe (32) away from the small water tank (31), and the detection end of the liquid level sensor (35) is located inside the small water tank (31).