A dynamic collection device for leaf litter bvocs simulating a natural environment
By designing a dynamic incubator and an artificial climate chamber, and combining modular in-situ sampling technology, the problem that the fallen leaf BVOCs sampling device could not truly simulate the natural environment was solved, and the complete preservation of the fallen leaf-soil interface and the true collection of BVOCs were achieved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- FUQING BRANCH OF FUJIAN NORMAL UNIV
- Filing Date
- 2025-09-29
- Publication Date
- 2026-07-14
AI Technical Summary
Existing leaf litter BVOCs sampling devices cannot realistically simulate changes in light, temperature, and humidity in the natural environment, lack diurnal rhythm variations, and fail to fully preserve the natural contact interface between fallen leaves and soil, resulting in significant differences between the BVOCs release characteristics collected and those in the field environment.
A dynamic collection device for BVOCs from fallen leaves, simulating a natural environment, was designed. It includes a dynamic incubator, an artificial climate chamber, and a control module, which can regulate light, temperature, and humidity. Through modular design, it can collect fallen leaves and topsoil in situ in the field, maintaining the integrity of the natural contact interface.
It achieves a realistic ecological simulation of BVOCs from fallen leaves, and can completely preserve the natural contact interface between fallen leaves and topsoil during collection. This overcomes the shortcomings of traditional devices in environmental simulation and improves the realism and representativeness of the collection.
Smart Images

Figure CN224499575U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of BVOCs emission monitoring technology, specifically to a dynamic BVOCs collection device for fallen leaves that simulates a natural environment. Background Technology
[0002] Biogenic volatile organic compounds (BVOCs) are a class of trace gaseous organic compounds emitted by plants, animals, and microorganisms. They play an important role in atmospheric chemical processes, plant-microorganism interactions, signal transduction between plants, herbivorous insects, and insect predators, and in plant resistance to abiotic stress. They are an important link in the study of regional atmospheric pollution generation and terrestrial ecosystem material cycling.
[0003] Currently, in the fields of environmental monitoring and global change ecology, monitoring devices for BVOCs emissions from non-living plant tissues such as fallen leaves utilize simple controlled experimental platforms consisting of artificial climate chambers and dynamic incubators. Before culturing the fallen leaves, topsoil collected from the sample location is prepared into a soil suspension, and 2 mL is evenly inoculated at the bottom of a PTFE incubator to provide a basic microbial inoculum. Although this method can initially introduce a microbial community, it cannot recreate the in-situ interface structure of the interaction between fallen leaves and soil and microorganisms under natural conditions. The micro-ecological environment is also relatively simplified, limiting the authenticity and representativeness of the collected BVOCs release characteristics. After the fallen leaves begin culturing, the artificial climate chamber is set with fixed light and temperature cycles, and water is replenished regularly during the experiment to ensure stable relative humidity within the incubator. However, because the artificial climate chamber only has simple light and temperature cycles set and humidity is not precisely controlled, the fallen leaves are often placed in a "dynamically dry" or even "statically dry" environment, and the BVOCs emission characteristics often differ significantly from those in the field environment.
[0004] Therefore, although existing BVOCs monitoring devices for non-living plant tissues such as fallen leaves have a certain degree of controllability, they still have many shortcomings. For example, due to the long decomposition cycle of fallen leaves, BVOCs sampling is often carried out in the laboratory, and the sampling devices are difficult to reproduce changes in light, temperature, and humidity in the natural environment, resulting in unrealistic environmental simulations; they lack simulation of key ecological factors such as diurnal rhythm changes; and they do not consider the actual interaction interface between fallen leaves and soil and microorganisms. Utility Model Content
[0005] Therefore, there is a need to provide a dynamic collection device for BVOCs from fallen leaves that simulates the natural environment, in order to solve the problem that existing BVOCs sampling devices for fallen leaves do not simulate diurnal rhythm changes and disrupt the in-situ interface structure of the fallen leaves interacting with the soil and microorganisms in their natural state during sampling.
[0006] To achieve the above objectives, the inventors provide a dynamic BVOCs collection device for fallen leaves that simulates a natural environment, comprising:
[0007] A dynamic incubator, which is equipped with a light control module, a temperature control module and a humidity control module to adjust the light intensity, temperature and humidity inside the dynamic incubator;
[0008] An artificial climate chamber includes a culture section, a sampling section, and a bottom cover that are detachably connected from top to bottom. The culture section, sampling section, and bottom cover enclose a culture cavity. The culture cavity is equipped with a detection module for detecting humidity, temperature, and light intensity.
[0009] The control module is connected to the detection module, the light adjustment module, the temperature adjustment module, and the humidity adjustment module.
[0010] In some embodiments, the sampling section and the bottom cover are made of inert stainless steel.
[0011] In some embodiments, the top end of the sampling segment is threadedly connected to the culture segment, and the bottom end of the segment is threadedly connected to the bottom cover.
[0012] In some embodiments, the artificial climate chamber further includes a top cover for temporarily covering the top of the sampling section.
[0013] In some embodiments, the artificial climate chamber further includes an insertable humidity detection module that can be inserted into the soil.
[0014] In some embodiments, the artificial climate chamber further includes a turbulence fan disposed within the culture chamber; the culture section has an air inlet and an air outlet.
[0015] In some embodiments, the artificial climate chamber is provided in two sets, namely a sample climate chamber and a control climate chamber.
[0016] In some embodiments, the illumination adjustment module includes an LED light with controllable light intensity.
[0017] In some embodiments, the LED light is an infinitely variable light.
[0018] In some embodiments, the temperature control module includes an atomizing humidifier connected to the air inlet of the dynamic incubator.
[0019] Unlike existing technologies, the above-described simulated natural environment leaf litter BVOCs dynamic collection device uses an artificial climate chamber consisting of a detachable culture section, a sampling section, and a bottom cover, connected sequentially from top to bottom. These components are modularly connected, forming a culture chamber. Removing the bottom cover and culture section allows the sampling section to be directly and vertically pressed into the ground surface in the field, collecting fallen leaves along with the covering topsoil in situ. This maintains the integrity of the soil column and preserves the natural leaf-soil contact interface, completely preserving the natural contact interface between the fallen leaves and the topsoil, thus avoiding problems such as changes in the microbial community. The culture chamber is equipped with a detection module for humidity, temperature, and light intensity. The dynamic incubator is equipped with a light regulation module, a temperature regulation module, and a humidity regulation module. The control module is connected to the detection module, the light regulation module, the temperature regulation module, and the humidity regulation module, thereby adjusting the light intensity, temperature, and humidity inside the dynamic incubator. It integrates a dynamic control system for light, temperature, and humidity, which can realistically reproduce the changes in the microenvironment under the forest. Therefore, the dynamic collection device for BVOCs from fallen leaves that simulates the natural environment can simulate the changes in diurnal rhythm. When collecting samples, it can completely preserve the natural contact interface between fallen leaves and the surface soil. Through systematic optimization of structure and function, it effectively solves many problems such as unrealistic environmental simulation in the traditional indoor culture of fallen leaves and BVOCs sampling process.
[0020] The above description of the utility model is merely an overview of the technical solution of this application. In order to enable those skilled in the art to better understand the technical solution of this application and to implement it based on the description and drawings, and to make the above-mentioned objectives and other objectives, features and advantages of this application easier to understand, the following description is provided in conjunction with the specific embodiments and drawings of this application. Attached Figure Description
[0021] The accompanying drawings are only used to illustrate the principles, implementation methods, applications, features, and effects of specific embodiments of this application and other related content, and should not be considered as limitations on this application.
[0022] In the accompanying drawings of the instruction manual:
[0023] Figure 1 A structural diagram of the artificial climate chamber described in the specific implementation method;
[0024] Figure 2 An exploded view of the artificial climate chamber described in the specific implementation method;
[0025] Figure 3 A cross-sectional view of the artificial climate chamber described in the specific implementation embodiment;
[0026] Figure 4 This is a structural diagram of the top surface inside the culture section as described in the specific implementation method;
[0027] Figure 5 This is a structural diagram of the top surface inside the dynamic incubator described in a specific embodiment;
[0028] Figure 6 This is a structural diagram of the dynamic incubator described in a specific embodiment;
[0029] The reference numerals used in the above figures are explained as follows:
[0030] 1. Artificial climate chamber;
[0031] 100. Cultivation stage;
[0032] 101. Sampling segment;
[0033] 102. Bottom cover;
[0034] 103. Top cover;
[0035] 104. Thread;
[0036] 105. Insertion-type humidity detection module;
[0037] 106. Temperature and humidity sensor;
[0038] 107. Optical sensor;
[0039] 108. Turbidity fan;
[0040] 109. Intake pipe;
[0041] 110. Air outlet pipe;
[0042] 2. Dynamic incubator;
[0043] 200. LED lights;
[0044] 201. Temperature control module;
[0045] 202. Atomizing humidifier;
[0046] 203. Control Panel;
[0047] 204. Brightness adjustment knob;
[0048] 205. Exhaust port;
[0049] 3. Air compressor;
[0050] 4. Filtration system;
[0051] 5. Fallen leaves;
[0052] 6. Soil. Detailed Implementation
[0053] To illustrate the possible application scenarios, technical principles, implementable specific solutions, and achievable objectives and effects of this application in detail, the following description, in conjunction with the listed specific embodiments and accompanying drawings, provides a detailed explanation. The embodiments described herein are merely illustrative of the technical solutions of this application and are therefore intended to limit the scope of protection of this application.
[0054] In this document, the term "embodiment" means that a specific feature, structure, or characteristic described in connection with an embodiment may be included in at least one embodiment of this application. The term "embodiment" appearing in various places throughout the specification does not necessarily refer to the same embodiment, nor does it specifically limit its independence or connection with other embodiments. In principle, in this application, as long as there are no technical contradictions or conflicts, the technical features mentioned in each embodiment can be combined in any way to form corresponding implementable technical solutions.
[0055] Unless otherwise defined, the technical terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application pertains; the use of related terms herein is merely for the purpose of describing particular embodiments and is not intended to limit this application.
[0056] In the description of this application, the term "and / or" is used to describe the logical relationship between objects, indicating that three relationships can exist. For example, A and / or B means: A exists, B exists, and A and B exist simultaneously. Additionally, the character " / " in this document generally indicates that the preceding and following objects have an "or" logical relationship.
[0057] In this application, 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 actual quantity, hierarchy or order relationship between these entities or operations.
[0058] Unless otherwise specified, the use of terms such as “comprising,” “including,” “having,” or other similar expressions in this application is intended to cover non-exclusive inclusion, which does not exclude the presence of additional elements in a process, method, or product that includes the stated elements, such that a process, method, or product that includes a list of elements may include not only those defined elements but also other elements not expressly listed, or elements inherent to such a process, method, or product.
[0059] Similar to the understanding in the Examination Guidelines, in this application, expressions such as "greater than," "less than," and "exceeding" are understood to exclude the stated number; expressions such as "above," "below," and "within" are understood to include the stated number. Furthermore, in the description of the embodiments in this application, "multiple" means two or more (including two), and similar expressions related to "multiple" are also understood in this way, such as "multiple groups" and "multiple times," unless otherwise explicitly specified.
[0060] In the description of the embodiments of this application, the space-related expressions used, such as "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "vertical," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," and "circumferential," indicate the orientation or positional relationship based on the orientation or positional relationship shown in the specific embodiments or drawings. They are only for the purpose of describing the specific embodiments of this application or for the reader's understanding, and do not indicate or imply that the device or component referred to must have a specific position, a specific orientation, or be constructed or operated in a specific orientation. Therefore, they should not be construed as limitations on the embodiments of this application.
[0061] Unless otherwise expressly specified or limited, the terms "installation," "connection," "linking," "fixing," and "setting," as used in the description of the embodiments of this application, should be interpreted broadly. For example, "connection" can be a fixed connection, a detachable connection, or an integral setting; it can be a mechanical connection, an electrical connection, or a communication connection; it can be a direct connection or an indirect connection through an intermediate medium; it can be the internal connection of two components or the interaction between two components. For those skilled in the art to which this application pertains, the specific meaning of the above terms in the embodiments of this application can be understood according to the specific circumstances.
[0062] Biogenic volatile organic compounds (BVOCs) are a class of trace gaseous organic compounds emitted by plants, animals, and microorganisms. They play an important role in atmospheric chemical processes, plant-microorganism interactions, signal transduction between plants, herbivorous insects, and insect predators, and in plant resistance to abiotic stress. They are an important link in the study of regional atmospheric pollution generation and terrestrial ecosystem material cycling.
[0063] Currently, in the fields of environmental monitoring and global change ecology, monitoring devices for BVOCs emissions from non-living plant tissues such as fallen leaves utilize simple controlled experimental platforms consisting of artificial climate chambers and dynamic incubators. Before culturing the fallen leaves, topsoil collected from the sample location is prepared into a soil suspension, and 2 mL is evenly inoculated at the bottom of a PTFE incubator to provide a basic microbial inoculum. Although this method can initially introduce a microbial community, it cannot recreate the in-situ interface structure of the interaction between fallen leaves and soil and microorganisms under natural conditions. The micro-ecological environment is also relatively simplified, limiting the authenticity and representativeness of the collected BVOCs release characteristics. After the fallen leaves begin culturing, the artificial climate chamber is set with fixed light and temperature cycles, and water is replenished regularly during the experiment to ensure stable relative humidity within the incubator. However, because the artificial climate chamber only has simple light and temperature cycles set and humidity is not precisely controlled, the fallen leaves are often placed in a "dynamically dry" or even "statically dry" environment, and the BVOCs emission characteristics often differ significantly from those in the field environment.
[0064] While existing BVOCs monitoring devices based on emissions from non-living plant tissues such as fallen leaves offer some controllability, they still have many shortcomings. For example, due to the long decomposition cycle of fallen leaves, BVOCs sampling is often conducted in the laboratory, making it difficult for the sampling devices to reproduce changes in light, temperature, and humidity in the natural environment, resulting in unrealistic environmental simulations. They also lack simulation of key ecological factors such as diurnal rhythm changes and do not consider the actual interaction interfaces between fallen leaves and soil or microorganisms.
[0065] Therefore, this utility model provides a dynamic collection device for BVOCs from fallen leaves that simulates the natural environment. This device is applicable to disciplines such as ecology, atmospheric chemistry, and global change research. In particular, it can simulate diurnal rhythm changes and completely preserve the natural contact interface between fallen leaves 5 and topsoil 6 when collecting samples. It provides stable and near-natural technical support for indoor decomposition experiments of non-living plant tissues and the collection and analysis of BVOCs, and has good application prospects in environmental monitoring and multidisciplinary scientific research.
[0066] In a specific embodiment, the simulated natural environment leaf litter BVOCs dynamic acquisition device includes a dynamic incubator 2, an artificial climate chamber 1, and a control module; the dynamic incubator 2 is equipped with a light adjustment module, a temperature adjustment module 201, and a humidity adjustment module to adjust the light intensity, temperature, and humidity inside the dynamic incubator 2; please refer to Figure 1 , Figure 2 and Figure 3The artificial climate chamber 1 includes a culture section 100, a sampling section 101, and a bottom cover 102 that are detachably connected from top to bottom. The culture section 100, the sampling section 101, and the bottom cover 102 form a culture cavity. The culture cavity is equipped with a detection module, which is used to detect humidity, temperature, and light intensity. The control module is connected to the detection module, the light adjustment module, the temperature adjustment module 201, and the humidity adjustment module.
[0067] The culture chamber is equipped with a detection module for humidity, temperature, and light intensity, which can detect the temperature, humidity, and light intensity inside the culture chamber in real time. The dynamic incubator 2 is equipped with a light adjustment module, a temperature adjustment module 201, and a humidity adjustment module. The light adjustment module can be controlled according to light requirements to adjust the light intensity, the temperature adjustment module 201 can be controlled according to temperature requirements to adjust the temperature, and the humidity adjustment module can be controlled according to humidity requirements to adjust the humidity. The control module is connected to the detection module, the light adjustment module, the temperature adjustment module 201, and the humidity adjustment module, integrating a dynamic control system for light, temperature, and humidity. Therefore, based on the temperature, humidity, and light intensity detected inside the culture chamber, as well as the dynamic changes in the typical environment of leaf litter decomposition 5 observed in the natural environment such as light intensity, temperature, and humidity at the forest canopy litter interface, the light intensity, temperature, and humidity inside the dynamic incubator 2 can be adjusted to realistically reproduce the changes in the forest microenvironment.
[0068] Specifically, the dynamic changes of typical environments for the decomposition of fallen leaves (5) such as light intensity, temperature, and humidity at the litter interface under the forest canopy in the natural environment are observed. Then, based on the observation results, under the control of the control module, the characteristics of natural light, temperature, and humidity changes are simulated to achieve dynamic regulation of the environment, change the current situation of "dynamic drying" or even "static drying" decomposition of fallen leaves (5), and truly restore the characteristics and cycles of light, temperature, and humidity changes under the forest canopy.
[0069] Please see Figure 1 The culture section 100, sampling section 101, and bottom cover 102 are modularly connected, and when the three are connected together, they form a culture chamber. Please refer to [link / reference]. Figure 2 By removing the bottom cover 102 and the cultivation section 100, the sampling section 101 can be directly and vertically pressed into the ground surface in the field to collect fallen leaves 5 along with the topsoil 6 covering them in situ. This can maintain the integrity of the soil column and prevent the natural contact interface structure of fallen leaves 5 and soil 6 from being disturbed. It can also completely preserve the natural contact interface between fallen leaves 5 and topsoil 6, avoiding problems such as changes in the microbial community.
[0070] Therefore, the simulated natural environment leaf BVOCs dynamic collection device can simulate diurnal rhythm changes and completely preserve the natural contact interface between the fallen leaves 5 and the surface soil 6 when collecting samples. Through systematic optimization of structure and function, it breaks through the limitations of traditional laboratory conditions for microbial suspension inoculation simulation, realizes a more realistic ecological simulation of the decomposition process of natural litter, and effectively solves many problems such as unrealistic environmental simulation in traditional indoor culture of fallen leaves and BVOCs sampling.
[0071] The artificial climate chamber 1 is a cylindrical box, cut from top to bottom into a culture section 100, a sampling section 101, and a bottom cover 102. In some embodiments, the culture section 100 is made of polytetrafluoroethylene (PTFE) and includes side plates and a top plate. Please refer to [link to relevant documentation]. Figure 1 The top plate is provided with two sampling ports, one of which is an air inlet and the other is an air outlet. The air inlet is connected to an air inlet pipe 109 and the air outlet is connected to an air outlet pipe 110.
[0072] In some embodiments, the sampling section 101 includes a side plate and openings at both ends, allowing it to be directly and vertically pressed into the ground surface to collect fallen leaves 5 along with the surface soil 6 covering them in situ. This maintains the integrity of the soil column and prevents disturbance to the natural contact interface structure between the fallen leaves 5 and the soil 6. An in-situ natural or simulated soil 6 interface is directly introduced at the bottom of the sampling section 101, enhancing the ability to reproduce the natural decomposition conditions of litter in the field.
[0073] In some embodiments, the bottom cover 102 includes a side plate and a bottom plate.
[0074] In some embodiments, the sampling section 101 and the bottom cover 102 are made of stainless steel.
[0075] In a further embodiment, the sampling section 101 and the bottom cover 102 are made of inert stainless steel, which has good airtightness and corrosion resistance.
[0076] In some embodiments, the top end of the sampling section 101 is connected to the culture section 100 by a thread 104, and the bottom end of the section is connected to the bottom cover 102 by a thread 104. The connection via the thread 104 structure allows for quick assembly and disassembly and provides good sealing.
[0077] Please see Figure 2In some embodiments, the artificial climate chamber 1 further includes a top cover 103, which is used to temporarily cover the top of the sampling section 101. After sampling is completed using the sampling section 101, the bottom cover 102 is installed at the bottom opening of the sampling section 101, and the top opening of the sampling section 101 is temporarily sealed by the top cover 103 to prevent moisture loss or microbial disturbance of the sample during transportation. After the fallen leaves 5 along with the surface soil 6 covering them are brought back to the laboratory, the top cover 103 is removed, and the sampling section 101 is directly connected to the culture section 100, thus achieving seamless embedding of the sampling section 101 into the culture section 100.
[0078] The modular design of the artificial climate chamber 1 effectively avoids structural damage caused by traditional sample removal, allowing the fallen leaves 5 to complete the decomposition process and BVOCs sample collection in an almost natural environment, thereby constructing a micro-decomposition and BVOCs collection unit that is closer to the wild ecosystem.
[0079] In some embodiments, the top end of the sampling section 101 is threaded to the top cover 103 104, which allows for quick assembly and disassembly and provides good sealing.
[0080] In some embodiments, the detection module includes a light detection module, a temperature detection module, and a humidity detection module. The humidity detection module is used to detect the humidity inside the culture chamber, the temperature detection module is used to detect the temperature inside the culture chamber, and the light detection module is used to detect the light intensity inside the culture chamber.
[0081] Please see Figure 4 In a further embodiment, the light detection module is a light sensor 107, which is located on the top plate of the culture section 100.
[0082] Please see Figure 4 In some embodiments, the temperature detection module and the humidity detection module are integrated into one unit, namely a temperature and humidity sensor 106, which is located on the top plate of the culture section 100.
[0083] Please see Figure 3 In some embodiments, the artificial climate chamber 1 further includes an insertable humidity detection module 105 that can be inserted into the soil 6. The insertable humidity detection module is an insertable humidity sensor, whose detection head is inserted into the soil 6 to detect the humidity of the soil 6. It can monitor and record the change process of soil moisture in real time, and then replenish the soil moisture accordingly, thereby further ensuring that the humidity of the soil 6 is close to the actual level under the forest.
[0084] Please see Figure 4 In some embodiments, the artificial climate chamber 1 further includes a turbulence fan 108 disposed within the culture chamber.
[0085] In some embodiments, the artificial climate chamber 1 is provided in two sets, namely a sample climate chamber and a control climate chamber. The sample climate chamber is filled with fallen leaves 5, and the control climate chamber is filled with PTFE fragments of equal mass. Thus, an "in-situ soil column with fallen leaves 5 removed" can be set as a blank control group to simulate physical covering without releasing biovolatiles, thereby effectively eliminating background BVOCs interference from the soil 6 or the device material itself, and ensuring the accuracy of the target BVOCs data.
[0086] In some embodiments, the illumination adjustment module includes an LED lamp 200 with controllable light intensity.
[0087] Please see Figure 5 In some embodiments, the LED lights 200 are provided in several groups, and the light intensity can be adjusted by changing the number of LED lights 200 that are turned on.
[0088] In some embodiments, the LED light 200 is a stepless dimming light. By controlling the stepless dimming light, the light intensity can be continuously and gradually adjusted to more realistically simulate the day-night rhythm changes of the natural environment.
[0089] In some embodiments, the LED light 200 is an infinitely variable light.
[0090] Please see Figure 6 In some embodiments, the control module includes a brightness adjustment knob 204, which is connected to a stepless dimming lamp so that the light intensity can be manually adjusted.
[0091] Please see Figure 6 In some embodiments, the control module further includes a control panel 203, which includes control keys and a display screen. The display screen shows the humidity, temperature and light intensity detected by the detection module, and the control keys control the temperature adjustment module 201 and the humidity adjustment module to adjust the temperature and humidity.
[0092] In a further embodiment, the dynamic incubator 2 is provided with an air inlet and an air outlet 205. The air inlet is supplied with air through an air compressor 3 and filtered by a filtration system 4.
[0093] In some embodiments, the temperature regulation module 201 includes an atomizing humidifier 202, which is connected to the air inlet of the dynamic incubator 2, and the humidity is regulated by the atomizing humidifier 202.
[0094] Finally, it should be noted that although the above embodiments have been described in the text and drawings of this application, this should not limit the scope of patent protection of this application. Any technical solutions that are based on the essential concept of this application and utilize the content described in the text and drawings of this application, resulting in equivalent structural or procedural substitutions or modifications, as well as the direct or indirect application of the technical solutions of the above embodiments to other related technical fields, are all included within the scope of patent protection of this application.
Claims
1. A device for dynamic collection of leaf litter BVOCs simulating natural environment, characterized in that, The utility model relates to a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation.
2. The device for dynamic collection of BVOCs from senesced leaves simulating natural environment according to claim 1, wherein, The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation.
3. The device for dynamic collection of BVOCs from senesced leaves in simulated natural environment according to claim 1, wherein, The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation.
4. The device for dynamic collection of BVOCs from senesced leaves in simulated natural environment according to claim 1, wherein, The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation.
5. The device for dynamic collection of BVOCs from senesced leaves in simulated natural environment according to claim 1, wherein, The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation.
6. The device for dynamic collection of BVOCs from senesced leaves simulating natural environment according to claim 1, wherein, The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation.
7. The device for dynamic collection of BVOCs from senesced leaves in simulated natural environment according to any one of claims 1-6, characterized in that, The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation.
8. The device for dynamic collection of BVOCs from senesced leaves in simulated natural environment according to claim 1, wherein, The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation.
9. The device for dynamic collection of BVOCs from senesced leaves simulating natural environment according to claim 8, characterized in that, The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation.
10. The device for dynamic collection of BVOCs from senesced leaves in simulated natural environment according to claim 1, characterized in that, The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility model discloses a dynamic incubator, artificial climate chamber and control module, and belongs to the field of plant cultivation. The utility