Carbon sequestration plantation filtration system
By designing a carbon-fixing planting filtration system that combines air intake pipes, plant fibers and carbon-based carbon fixation layers, and an AI monitoring system, the system integrates the condensation and solidification of carbon dioxide in the air with plant growth, solving the problems of reduced fertilizer use and global warming, and achieving multiple goals of environmental purification and plant growth.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 何姿雨
- Filing Date
- 2025-07-15
- Publication Date
- 2026-07-07
AI Technical Summary
In the context of industrialization and climate warming, existing technologies struggle to effectively reduce fertilizer use, promote economic development, and simultaneously achieve carbon sequestration and air filtration.
Design a carbon fixation planting and filtration system, including a planting chamber, an air inlet pipe, a plant fiber and carbon-based carbon fixation layer, and a planting layer. Combined with an AI monitoring system, it can achieve the coagulation and solidification of trace elements such as carbon dioxide and harmful substances in the air. By planting plants in the planting layer, carbon fixation and air filtration are integrated.
It achieves the adsorption of beneficial substances and the filtration of harmful substances in the air, saves fertilizer use, naturally filters harmful substances in the air, promotes plant growth, mitigates climate warming, and requires no additional filter materials or equipment maintenance.
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Figure CN224462501U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of carbon sequestration planting technology, and more particularly to a carbon sequestration planting filtration system. Background Technology
[0002] Against the backdrop of continuous industrialization, increasing total energy consumption, decreasing planting area, and gradual global warming, how to apply "carbon sequestration technology" to reduce fertilizer use, promote economic development, and address climate change has become a key challenge. Utility Model Content
[0003] In view of the above problems, the embodiments of this application provide a carbon fixation planting filtration system, which overcomes the above problems or at least partially solves the above problems.
[0004] According to one aspect of the embodiments of this application, a carbon fixation planting filtration system is provided, including a planting chamber having a receiving groove; an air inlet pipe, a plant fiber and carbon-based carbon fixation layer, and a planting layer are sequentially arranged from the bottom to the opening of the receiving groove; the air inlet pipe is connected to the plant fiber and carbon-based carbon fixation layer so that air entering from the air inlet pipe can enter the plant fiber and carbon-based carbon fixation layer; the planting layer is used for planting plants.
[0005] In one alternative embodiment, the carbon sequestration planting filtration system further includes a detection device and an AI monitoring system. The detection end of the detection device is located in the receiving tank, and the detection device is communicatively connected to the AI monitoring system, which is located on one side of the planting chamber.
[0006] In one alternative approach, the detection device includes a soil monitor with its detection end located in the planting layer, and the soil monitor is communicatively connected to the AI monitoring system.
[0007] In one alternative embodiment, the detection device further includes a biomass detector, the detection end of which is located on the plant fiber and carbon-based carbon fixation layer, and the biomass detector is communicatively connected to the AI monitoring system.
[0008] In one alternative embodiment, along the direction from the bottom to the opening of the receiving tank, the air inlet pipe is spaced apart from the plant fiber and the carbon-based carbon fixation layer to form a gap. The detection device also includes an air detection device, the detection end of which is located in the gap, and the air detection device is communicatively connected to the AI monitoring system.
[0009] In one alternative approach, there are multiple air inlet pipes, which are arranged at intervals at the bottom of the receiving tank. There are also several air detection devices, with one air detection device placed between two adjacent air inlet pipes.
[0010] In one alternative embodiment, the planting chamber is provided with an exhaust device located at one end of the air inlet duct.
[0011] In one alternative embodiment, the carbon fixation planting filtration system further includes a support member disposed on one side of the planting chamber, the AI monitoring system disposed on the support member, the support member having a through hole corresponding to the exhaust device, the through hole being used for air to enter the air inlet pipe from the exhaust device.
[0012] In one alternative embodiment, the carbon fixation planting filtration system further includes a water injection pipe disposed in the planting layer.
[0013] In one alternative, the water inlet pipe extends to the bottom of the planting layer.
[0014] The beneficial effects of this application embodiment are as follows: A carbon fixation planting filtration system is provided, including a planting chamber with a receiving groove; an air inlet pipe, a plant fiber and carbon-based carbon fixation layer, and a planting layer are sequentially arranged from the bottom to the opening of the receiving groove; the air inlet pipe is connected to the plant fiber and carbon-based carbon fixation layer so that air entering from the air inlet pipe can enter the plant fiber and carbon-based carbon fixation layer; the planting layer is used for planting plants. Through this carbon fixation planting filtration system, the air inlet pipe is connected to the plant fiber and carbon-based carbon fixation layer, ensuring that air can flow smoothly into the plant fiber and carbon-based carbon fixation layer; in the plant fiber and carbon-based carbon fixation layer, trace elements such as carbon dioxide, nitrogen, argon, phosphorus, and potassium and harmful substances in the air entering from the air inlet pipe are condensed and solidified, which not only achieves the adsorption of beneficial substances in the air and saves the use of chemical fertilizers, but also naturally filters harmful substances in the air, without the need to use other filter materials or filters, and without the need to replace filter materials and filters; by planting plants in the planting layer, planting, carbon dioxide fixation and air filtration are integrated, achieving multiple purposes of environmental purification, mitigating global warming and promoting plant growth. Attached Figure Description
[0015] One or more embodiments are illustrated by way of example with reference numerals in the accompanying drawings. These illustrations do not constitute a limitation on the embodiments. Elements with the same reference numerals in the drawings are denoted as similar elements. Unless otherwise stated, the figures in the drawings are not to be limited by scale.
[0016] Figure 1 This is a top view of the carbon sequestration and filtration system provided in the embodiments of this application.
[0017] Figure 2 The planting chamber provided in this application embodiment is along Figure 1 A sectional view of A in the middle.
[0018] Figure 3 This is a cross-sectional view of the air intake duct of the carbon sequestration and filtration system provided in this application embodiment.
[0019] Figure 4 This is a front view of the AI monitoring system provided in this embodiment of the application, installed on the support.
[0020] The labels in the attached diagram are as follows:
[0021] 10. Carbon sequestration planting filtration system;
[0022] 1. Planting chamber; 2. Air intake duct; 3. Plant fiber and carbon-based carbon fixation layer; 4. Planting layer; 5. Detection device; 6. AI monitoring system; 7. Exhaust equipment; 8. Support components; 9. Water injection pipe;
[0023] 11. Reception slot;
[0024] 21. Air intake;
[0025] 51. Soil detector; 52. Biomass detector; 53. Air quality monitoring equipment;
[0026] 81. Through hole;
[0027] 91. Drainage hole;
[0028] s, gap. Detailed Implementation
[0029] To facilitate understanding of this application, a more detailed description is provided below with reference to the accompanying drawings and specific embodiments. It should be noted that when an element is described as being "fixed to" another element, it can be directly attached to the other element, or one or more intermediate elements may exist between them. When an element is described as being "connected to" another element, it can be directly connected to the other element, or one or more intermediate elements may exist between them. The terms "vertical," "horizontal," "left," "right," "inner," "outer," and similar expressions used in this specification are for illustrative purposes only.
[0030] Unless otherwise defined, all technical and scientific terms used in this specification have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used in this specification is for the purpose of describing particular embodiments only and is not intended to limit the scope of the application. The term "and / or" as used in this specification includes any and all combinations of one or more of the associated listed items.
[0031] Please see Figure 1 and Figure 2 This application provides a carbon fixation planting filtration system 10, including a planting chamber 1, which has a receiving groove 11; an air inlet pipe 2, a plant fiber and carbon-based carbon fixation layer 3, and a planting layer 4 are arranged sequentially from the bottom to the opening of the receiving groove 11; the air inlet pipe 2 is connected to the plant fiber and carbon-based carbon fixation layer 3 so that the air entering from the air inlet pipe 2 can enter the plant fiber and carbon-based carbon fixation layer 3; the planting layer 4 is used for planting plants. With the help of this carbon sequestration planting and filtration system 10, air enters through the air inlet pipe 2 and connects with the plant fibers and carbon-based carbon sequestration layer 3, ensuring that the air can flow smoothly into the plant fibers and carbon-based carbon sequestration layer 3. In the plant fibers and carbon-based carbon sequestration layer 3, trace elements such as carbon dioxide, nitrogen, argon, phosphorus, and potassium, as well as harmful substances in the air entering through the air inlet pipe 2, are condensed and solidified. This not only achieves the adsorption of beneficial substances in the air and saves the use of chemical fertilizers, but also naturally filters harmful substances in the air. There is no need to use other filter materials or filters, and there is no need to replace filter materials or filters. Plants are planted through the planting layer 4, achieving the integration of planting, carbon dioxide sequestration and air filtration, realizing multiple goals of environmental purification, mitigating global warming and promoting plant growth.
[0032] It is understood that the air inlet pipe 2 may be provided with an air inlet 21, which is used for air to flow from the air inlet pipe 2 into the plant fiber and carbon-based carbon fixation layer 3.
[0033] It is worth noting that in some embodiments, the carbon sequestration planting and filtration system 10 further includes a detection device 5 and an AI (Artificial Intelligence) monitoring system 6. The detection end of the detection device 5 is located in the receiving tank 11, and the detection device 5 is communicatively connected to the AI monitoring system 6. The AI monitoring system 6 is located on one side of the planting chamber 1, enabling real-time monitoring of environmental parameters within the planting chamber 1. Specifically, the detection device 5 may include various sensors for monitoring key indicators such as soil moisture, nutrient content, plant growth status, and air quality within the planting chamber 1. This data is transmitted to the AI monitoring system 6 wirelessly or via wired connection. The AI monitoring system 6 uses preset algorithms to analyze and process the data, providing users with planting suggestions and optimization solutions.
[0034] It is worth noting that the AI monitoring system 6 uses existing procedures.
[0035] It is worth noting that in some embodiments, the AI monitoring system 6 is connected to the wireless control system for wireless control of the carbon sequestration and filtration system 10.
[0036] It is worth noting that in some embodiments, the detection device 5 includes a soil monitor 51, the detection end of which is located in the planting layer 4. The soil monitor 51 is communicatively connected to the AI monitoring system 6. Through this soil monitor 51, key information such as soil moisture, pH, and nutrient content within the planting layer 4 can be acquired in real time. This information is crucial for the precise management of the plant growth environment. For example, when the soil moisture is too low, the AI monitoring system 6 can immediately identify this and remind the user to irrigate. This refined management can significantly improve plant growth efficiency.
[0037] It is worth noting that in some embodiments, the detection device 5 further includes a biomass detector 52. The detection end of the biomass detector 52 is located between the plant fiber and the carbon-based carbon fixation layer 3. The biomass detector 52 is communicatively connected to the AI monitoring system 6. Through the setting of the biomass detector 52, the biomass detector 52 can monitor the changes in biomass in the plant fiber and carbon-based carbon fixation layer 3 in real time, including key indicators such as the decomposition rate of organic matter and microbial activity. These data provide an important basis for evaluating the carbon fixation effect and optimizing the design of the carbon fixation layer. In addition, by comprehensively analyzing the data from the biomass detector 52, the AI monitoring system 6 can further adjust the environmental conditions inside the planting chamber 1 to promote a more efficient carbon fixation process and optimize the plant growth environment.
[0038] It is worth noting that in some embodiments, along the direction from the bottom to the opening of the receiving tank 11, the air inlet pipe 2 and the plant fiber and carbon-based carbon fixation layer 3 are spaced apart to form a gap s. The detection device 5 also includes an air detection device 53, the detection end of which is located in the gap s. The air detection device 53 is communicatively connected to the AI monitoring system 6. Through this air detection device 53, the air detection device 53 can monitor the air quality in the gap s formed between the air inlet pipe 2 and the plant fiber and carbon-based carbon fixation layer 3 in real time, including key indicators such as carbon dioxide concentration, oxygen content, humidity, and any potentially harmful gases. This data is crucial for assessing the plant's growth environment and optimizing airflow design. In addition, by receiving and analyzing the data from the air detection device 53, the AI monitoring system 6 can adjust the flow rate and speed of the air inlet pipe 2 in a timely manner to maintain an ideal air environment within the planting chamber 1, thereby promoting healthy plant growth and improving carbon fixation efficiency.
[0039] It is worth noting that in some embodiments, please refer to [link / reference]. Figure 3 The system comprises multiple air inlet pipes 2, spaced apart at the bottom of the receiving tank 11. It also includes several air detection devices 53, one of which is positioned between every two adjacent air inlet pipes 2. This design of multiple air inlet pipes 2 ensures that more air is evenly distributed into the plant fibers and carbon-based carbon fixation layer 3, improving carbon fixation efficiency. Simultaneously, the air detection devices 53 positioned between adjacent air inlet pipes 2 can monitor the air quality in each area in real time, providing more comprehensive data support for the AI monitoring system 6, thereby enabling precise control of the environment within the planting chamber 1. Furthermore, the combined use of multiple air inlet pipes 2 and several air detection devices 53 enhances the stability and reliability of the system. Even if one air inlet pipe 2 or air detection device 53 malfunctions, the other air inlet pipes 2 and air detection devices 53 can continue to operate, ensuring the continuous operation of the carbon fixation planting filtration system 10.
[0040] It is understood that the number of air detection devices 53 is one less than the number of air inlet pipes 2. For example, the number of air inlet pipes 2 is 4 and the number of air detection devices 53 is 3.
[0041] It is worth noting that in some embodiments, please refer to [link / reference]. Figure 3 The planting chamber 1 is equipped with an exhaust device 7, which is located at one end of the air inlet pipe 2. The exhaust device 7 promotes the entry of air into the pipe 2.
[0042] In some embodiments, the exhaust device 7 is a fan.
[0043] It is worth noting that in some embodiments, please refer to [link / reference]. Figure 2 and Figure 4 The carbon fixation planting filtration system 10 also includes a support member 8, which is disposed on one side of the planting chamber 1. The AI monitoring system 6 is disposed on the support member 8. The support member 8 has a through hole 81, which corresponds to the exhaust device 7. The through hole 81 allows air to enter the air inlet pipe 2 from the exhaust device 7. Through the through hole 81, the exhaust device 7 can generate a certain negative pressure, attracting external air to enter the air inlet pipe 2 through the through hole 81 of the support member 8, and then flow into the plant fibers and carbon-based carbon fixation layer 3. This design not only improves air circulation efficiency but also helps maintain the freshness and suitability of the air in the planting chamber 1, creating a more favorable environmental condition for plant growth.
[0044] It is worth noting that, please refer to Figure 3 And refer to Figure 2 and Figure 4 When there are multiple air inlet pipes 2, there are also multiple exhaust devices 7, the number of which is the same as the number of air inlet pipes 2, and one exhaust device 7 is disposed at one end of one air inlet pipe 2. There are also multiple through holes 81, the number of which is the same as the number of exhaust devices 7, and one through hole 81 corresponds to one exhaust device 7.
[0045] It is worth noting that in some embodiments, please refer to [link / reference]. Figure 2 The carbon fixation planting filtration system 10 also includes a water injection pipe 9, which is disposed in the planting layer 4. Through the placement of the water injection pipe 9, water can be conveniently injected into the planting layer 4 to meet the growth needs of the plants.
[0046] Furthermore, the water injection pipe 9 can be connected to the AI monitoring system 6. Based on soil moisture data monitored by the soil monitor 51, the AI monitoring system 6 controls the opening and closing of the water injection pipe 9 to achieve precise irrigation. This irrigation method not only effectively avoids water waste but also ensures that plants are always in the optimal growing environment. In some embodiments, the water injection pipe 9 is equipped with a solenoid valve, which is electrically connected to the AI monitoring system 6. The AI monitoring system 6 controls the water output of the water injection pipe 9 by controlling the opening and closing of the solenoid valve.
[0047] It is worth noting that in some embodiments, the water injection pipe 9 extends to the bottom of the planting layer 4. This arrangement ensures that water penetrates evenly into all parts of the planting layer 4, especially the bottom, which is particularly important for the growth of deep-rooted plants. In this way, water utilization efficiency can be maximized while reducing water evaporation and waste.
[0048] It is worth noting that the water injection pipe 9 can be provided with multiple distributed drainage holes 91 so that water can penetrate evenly into the planting layer 4, providing the plants with a more sufficient and uniform water supply.
[0049] In summary, the carbon sequestration planting filtration system 10 provided in this application has advantages such as compact structure, comprehensive functions, and high level of intelligence. Through the design of connecting the air inlet pipe 2 with the plant fibers and carbon-based carbon sequestration layer 3, effective air sequestration and healthy plant growth are achieved. Simultaneously, with the real-time monitoring and control functions of the AI monitoring system 6, users can easily understand the environmental parameters and plant growth status within the planting chamber 1 and make corresponding adjustments and optimizations. This carbon sequestration planting filtration system 10 not only helps alleviate global warming and reduce the use of chemical fertilizers, but also naturally filters harmful substances in the air, eliminating the need for additional filter materials or filters, and even the need to replace filter materials and filters, providing superior environmental conditions for plant growth and possessing broad application prospects.
[0050] It should be noted that while preferred embodiments of this application are provided in the specification and accompanying drawings, this application can be implemented in many different forms and is not limited to the embodiments described herein. These embodiments are not intended to impose additional limitations on the content of this application; their purpose is to provide a more thorough and comprehensive understanding of the disclosure of this application. Furthermore, the above-described technical features can be combined with each other to form various embodiments not listed above, all of which are considered to be within the scope of this application's specification. Moreover, those skilled in the art can make improvements or modifications based on the above description, and all such improvements and modifications should fall within the protection scope of the appended claims.
Claims
1. A carbon fixation planting filtration system, characterized in that, include: The planting chamber has a receiving slot; An air inlet pipe, a plant fiber and carbon-based carbon fixation layer, and a planting layer are sequentially arranged from the bottom to the opening of the receiving tank. The air inlet pipe is connected to the plant fiber and carbon-based carbon fixation layer so that the air entering from the air inlet pipe can enter the plant fiber and carbon-based carbon fixation layer. The planting layer is used to grow plants.
2. The carbon fixation planting filtration system according to claim 1, characterized in that, The carbon sequestration planting and filtration system also includes a detection device and an AI monitoring system. The detection end of the detection device is located in the receiving tank, and the detection device is communicatively connected to the AI monitoring system, which is located on one side of the planting chamber.
3. The carbon fixation planting filtration system according to claim 2, characterized in that, The detection device includes a soil monitor, the detection end of which is located in the planting layer, and the soil monitor is communicatively connected to the AI monitoring system.
4. The carbon fixation planting filtration system according to claim 2, characterized in that, The detection device also includes a biomass detector, the detection end of which is located on the plant fiber and carbon-based carbon fixation layer, and the biomass detector is communicatively connected to the AI monitoring system.
5. The carbon fixation planting filtration system according to claim 2, characterized in that, Along the direction from the bottom to the opening of the receiving tank, the air inlet pipe and the plant fiber and carbon-based carbon fixation layer are spaced apart to form a gap. The detection device also includes an air detection device, the detection end of which is located in the gap, and the air detection device is communicatively connected to the AI monitoring system.
6. The carbon fixation planting filtration system according to claim 5, characterized in that, The number of air inlet pipes is multiple, and the multiple air inlet pipes are arranged at intervals at the bottom of the receiving tank. The number of air detection devices is several, and one air detection device is set between two adjacent air inlet pipes.
7. The carbon fixation planting filtration system according to claim 2, characterized in that, The planting chamber is equipped with an exhaust device, which is located at one end of the air inlet pipe.
8. The carbon fixation planting filtration system according to claim 7, characterized in that, The carbon fixation planting filtration system also includes a support component, which is disposed on one side of the planting chamber. The AI monitoring system is disposed on the support component. The support component has a through hole, which corresponds to the exhaust device and is used for air to enter the air inlet pipe from the exhaust device.
9. The carbon fixation planting filtration system according to any one of claims 1-8, characterized in that, The carbon fixation planting filtration system also includes a water injection pipe, which is disposed in the planting layer.
10. The carbon fixation planting filtration system according to claim 9, characterized in that, The water injection pipe extends to the bottom of the planting layer.