Behavioral Observation Panoramic Recording Cabin
By installing components such as humidity sensors, temperature sensors, heating tubes, fans, and atomizing nozzles inside the recording chamber, precise control of the temperature and humidity of the recording chamber and efficient monitoring of animal behavior were achieved, solving the problem of insufficient temperature and humidity regulation and improving the reliability and practicality of experimental data.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- XINJIANG MEDICAL UNIV
- Filing Date
- 2025-08-08
- Publication Date
- 2026-06-30
AI Technical Summary
The existing recording chamber lacks effective dynamic control of temperature and humidity, and cannot accurately set and maintain stable temperature and humidity parameters according to the physiological needs of animals or the research objectives of behavior, resulting in reduced reliability of experimental data.
A panoramic recording cabin for behavioral observation was designed, equipped with humidity and temperature sensors. Temperature is regulated by heating tubes and fans, humidity is regulated by atomizing nozzles, and animal behavior is monitored by multi-angle cameras and photoelectric sensors, achieving precise control of temperature and humidity and data recording.
It improves the ability to regulate temperature and humidity inside the recording chamber and the reliability of data, ensuring animal comfort and the accuracy of behavioral recording, reducing stress response, and improving the reliability and practicality of experimental data.
Smart Images

Figure CN224419679U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of recording cabin technology, and in particular to a panoramic recording cabin for behavioral observation. Background Technology
[0002] Animal behavior refers to the observable activities or reactions exhibited by animals in natural or artificial environments. It is the result of their interaction with the environment, other individuals, or their own physiological state. Behavior is the core mechanism for animals to adapt to the environment, acquire resources, reproduce, and maintain survival, encompassing everything from simple reflexes to complex social strategies. The behavior observation panoramic recording chamber is a highly specialized experimental device in animal behavior research, helping researchers systematically and accurately analyze animal behavior patterns, social interactions, cognitive abilities, and environmental adaptability.
[0003] In existing technologies, the temperature and humidity environment inside the recording chamber lacks effective dynamic control capabilities during long-term observation and recording. Researchers cannot accurately set and maintain stable temperature and humidity parameters according to the physiological needs of animals or the goals of behavioral research. This causes the environment inside the chamber to frequently deviate from the preset ideal threshold. Animals exposed to unnatural temperature and humidity combinations for a long time are prone to adaptive defects such as increased stress response. More seriously, environmental fluctuations may mask the true behavioral patterns of animals, interfering with researchers' judgment of circadian rhythms or social interaction patterns. Ultimately, this leads to reduced data reliability, questionable generalizability of conclusions, and even the need for repeated observation and recording to eliminate environmental interference, significantly increasing research costs and time investment. Therefore, it is necessary to improve the behavior observation panoramic recording chamber to solve the above problems. Utility Model Content
[0004] To overcome the problem that the temperature and humidity environment in the recording chamber lacks effective dynamic control capabilities, researchers are unable to accurately set and maintain stable temperature and humidity parameters according to the physiological needs of animals or the goals of behavioral research, which leads to a decrease in the reliability of experimental data.
[0005] The technical solution of this utility model is as follows: a panoramic recording cabin for behavioral observation, including a support frame, a door panel rotatably connected to the support frame via a rotating component, a viewing glass fixedly connected to the inside of the support frame, a recording component disposed inside the support frame, a humidity sensor fixedly connected to the inside of the viewing glass, a temperature sensor fixedly connected to the inside of the viewing glass, a rigid tube rotatably connected to the inside of the support frame, an atomizing nozzle fixedly connected to the rigid tube, a universal adapter fixedly connected to the support frame, a connecting hose fixedly connected to the side of the universal adapter away from the rigid tube, a rotating rod rotatably connected to the inside of the support frame, a fan fixedly connected to the inside of the rotating rod, a fixed frame fixedly connected to the fan, and a heating tube fixedly connected to the inside of the fixed frame. The rigid tube is disposed on the universal adapter, allowing observation of the inner cavity of the support frame through the viewing glass, and enabling monitoring and recording of animals inside the device through the recording component.
[0006] Preferably, the viewing glass has ventilation slots for ventilation, and there are two sets of ventilation slots, which are symmetrically distributed on the viewing glass.
[0007] Preferably, an illumination lamp for illuminating the interior of the device is fixedly connected to the inner side of the viewing glass, a gear is fixedly connected to the rotating rod, the gear is fixedly connected to the rigid tube, a toothed plate is slidably connected inside the support frame, the gear meshes with the outside of the toothed plate, a connecting block is fixedly connected to the bottom of the toothed plate, a hydraulic telescopic rod is fixedly connected to the support frame, and the connecting block is fixedly connected to the telescopic end of the hydraulic telescopic rod.
[0008] Preferably, two sets of gears, toothed plates, connecting blocks, and hydraulic telescopic rods are provided, with the two sets of gears, toothed plates, connecting blocks, and hydraulic telescopic rods distributed sequentially at corresponding positions on the rotating rod and the rigid tube.
[0009] Preferably, the support frame has a matching limiting groove at the corresponding position of the toothed plate, and the toothed plate slides within the limiting groove of the support frame.
[0010] Preferably, the recording assembly includes a PLC controller fixedly connected to the inner wall of the support frame, a mounting frame fixedly connected to the inner wall of the support frame, a first motor fixedly connected to the mounting frame, a first rotating bracket fixedly connected to the output end of the first motor, a second motor fixedly connected to the mounting frame, a second rotating bracket fixedly connected to the output end of the second motor, a fixed frame fixedly connected to the mounting frame, a spherical frame slidably connected to the fixed frame, a movable frame slidably connected to the spherical frame, a support rod fixedly connected to the movable frame, a camera fixedly connected to the end of the support rod away from the movable frame, and a photoelectric sensor fixedly connected to the camera. The second rotating bracket is rotatably connected inside the mounting frame, the second motor is electrically connected to the PLC controller, the first rotating bracket is rotatably connected inside the mounting frame, the first motor is electrically connected to the PLC controller, the support rod is disposed inside the first rotating bracket, and the support rod is disposed in the groove of the second rotating bracket.
[0011] Preferably, the spherical frame has a matching limiting groove at the corresponding position of the fixed frame, the fixed frame is set in the limiting groove of the spherical frame, and the spherical frame has a matching limiting groove at the corresponding position of the movable frame, the movable frame slides in the limiting groove of the spherical frame.
[0012] Preferably, the first rotating bracket has a matching through groove at the corresponding position of the support rod, and the support rod is disposed inside the through groove of the first rotating bracket; similarly, the second rotating bracket has a matching through groove at the corresponding position of the support rod, and the support rod is disposed inside the through groove of the second rotating bracket.
[0013] The beneficial effects of this utility model are:
[0014] 1. The device uses humidity and temperature sensors to detect the temperature and humidity inside the recording chamber. When the temperature is low, the air heated by the heating element is blown into the recording chamber, and the fan rotates back and forth to increase the airflow range and improve the uniformity of temperature rise inside the recording chamber. When the recording chamber is relatively dry, atomized water is sprayed into the recording chamber through atomizing nozzles. The atomizing nozzles rotate back and forth to increase the spray range, making it easier to control the temperature and humidity inside the recording chamber. This improves the ability to regulate the temperature and humidity inside the recording chamber, enhances the reliability of behavioral recording data, and improves the practicality of the device.
[0015] 2. By sliding the spherical frame on the fixed frame, the horizontal angle of the camera can be adjusted. Then, by sliding the movable frame on the spherical frame, the vertical angle of the camera can be adjusted. This makes it easier to follow the animal's movements and film, thus improving the recording effect of the animal. Attached Figure Description
[0016] Figure 1This is a schematic diagram of one embodiment of the panoramic recording cabin for behavioral observation of this utility model;
[0017] Figure 2 This is a schematic diagram of the humidity sensor and temperature sensor of this utility model;
[0018] Figure 3 This is a schematic diagram of the universal adapter structure of this utility model;
[0019] Figure 4 This is a schematic diagram of the heating tube structure of this utility model;
[0020] Figure 5 This is a schematic diagram of the gear and gear plate structure of this utility model.
[0021] Figure 6 This is a schematic diagram of the recording component structure of this utility model;
[0022] Figure 7 This is a schematic diagram of the camera structure of this utility model;
[0023] Figure 8 This is a schematic diagram of the spherical frame structure of this utility model.
[0024] Explanation of reference numerals in the attached drawings: 1. Support frame; 21. Humidity sensor; 22. Temperature sensor; 23. Lighting lamp; 24. Rigid pipe; 25. Atomizing nozzle; 26. Universal adapter; 27. Connecting hose; 28. Rotating rod; 29. Fan; 210. Fixed frame; 211. Heating element; 212. Gear; 213. Tooth plate; 214. Connecting block; 215. Hydraulic telescopic rod; 31. PLC controller; 32. Mounting frame; 33. First motor; 34. First rotating bracket; 35. Second motor; 36. Second rotating bracket; 37. Fixed frame; 38. Spherical frame; 39. Movable frame; 310. Support rod; 311. Camera; 312. Photoelectric sensor; 4. Door panel; 5. Viewing glass. Detailed Implementation
[0025] The present invention will be further described below with reference to the accompanying drawings and embodiments.
[0026] Throughout the development of animal behavior science, traditional research methods have long been limited by observation efficiency and data accuracy. Early manual observation methods relied on researchers' naked-eye recording, which suffered from significant subjective bias and difficulties in data quantification. For example, in studying mouse social behavior, the error rate of manually counting contact frequencies could reach 20%-30%, and it was difficult to capture instantaneous behavioral characteristics. With the popularization of video recording technology, although the traceability of behavioral data has been achieved, the limitation of a single camera's perspective leads to a single dimension of behavioral analysis, and the accuracy rate of individual identification in complex social scenarios is less than 60%. In addition, the challenge of synchronizing data from multiple devices results in a spatiotemporal alignment error of hundreds of milliseconds between bioelectrical signals and behavioral videos, severely restricting research on the correlation between neural mechanisms and behavioral phenotypes.
[0027] The creation of the panoramic recording cabin for behavioral observation stems from the deep integration of animal behavior research and intelligent sensing technology. In traditional animal behavior research, researchers have long relied on a combination of manual observation and video playback, which suffers from bottlenecks such as low data acquisition efficiency, significant subjective bias, and difficulties in multi-dimensional behavioral correlation analysis. With breakthroughs in computer vision, multi-sensor fusion, and artificial intelligence algorithms, the panoramic recording cabin, by constructing a three-dimensional immersive observation environment, enables all-weather, high-precision, and multi-modal recording of the natural behavior of experimental animals.
[0028] This technological system can be traced back to the in-cabin perception system of the intelligent cockpit. Its core architecture includes hardware units such as a multi-camera array, an infrared depth sensor, and a bioelectrical signal acquisition module. Combined with spatial positioning algorithms and behavior recognition models, it forms a closed-loop system of "perception-reconstruction-analysis". The extravehicular activity virtual reality simulation system developed by the China Astronaut Research and Training Center provides an important reference for the spatial perception technology of the panoramic recording cabin through 1:1 scale 3D scene modeling and interactive operation design.
[0029] An innovative flexible electrode array has been developed to non-invasively collect EEG, ECG, and EMG signals from experimental animals. A time synchronization module enables nanosecond-level alignment of bioelectrical signals with behavioral videos. In a fear conditioning experiment, the system successfully captured a strong correlation between hippocampal theta wave amplitude and standstill behavior during fear memory formation.
[0030] To address interference factors such as changes in lighting conditions and equipment obstruction in the experimental environment, an adaptive exposure control and occlusion compensation mechanism was developed. When there are sudden changes in lighting intensity, the system can adjust exposure parameters within 50ms to ensure the continuity of the video stream. For static obstructions such as breeding cages, a deep learning-based image inpainting algorithm is used to restore behavioral details in the obstructed areas.
[0031] The system integrates a virtual reality engine, supporting the overlay of virtual stimuli onto panoramic recordings. For example, in object recognition experiments, the system can generate virtual objects and track animal exploratory behavior in real time. Through a multi-mode interactive operation paradigm using a controller, researchers can dynamically adjust the position, color, and other attributes of virtual objects, achieving a closed-loop research process of "observation-intervention-re-observation."
[0032] Develop a self-cleaning experimental chamber and an intelligent feeding system to support continuous behavioral monitoring for more than 30 days. Establish a behavioral data anonymization algorithm to achieve data sharing while protecting animal welfare. Employ a federated learning framework to conduct multi-center collaborative research while ensuring data privacy.
[0033] By combining two-photon microscopy with a panoramic recording chamber, simultaneous observation of neuronal activity and macroscopic behavior was achieved. Preliminary experiments showed enhanced phase synchrony of prefrontal cortex neuronal clusters during mouse decision-making, establishing a unified behavioral analysis framework that supports multi-species data comparison from nematodes to primates. In social behavior research, conserved interaction patterns were found among different species (e.g., the spatiotemporal similarity of mother-infant contact reached 73%).
[0034] The system quantitatively analyzed indicators such as the number of open-arm entry attempts and dwell time. The open-arm entry rate in mice treated with diazepam increased to 68%, with a 94% consistency rate with behavioral scores. The MPTP-induced Parkinson's disease monkey model exhibited bradykinesia (a 59% decrease in gait frequency) and postural abnormalities (a 42° increase in trunk flexion angle). The automatically generated movement disorder index showed a correlation of 0.91 with the clinical UPDRS score.
[0035] A distributed computing cluster was built to support the storage and analysis of petabyte-scale behavioral data. Parallel processing was achieved through the Spark framework, improving the efficiency of group behavior pattern mining by more than 10 times.
[0036] As a next-generation infrastructure for animal behavior research, the panoramic recording cabin for behavioral observation is reshaping the experimental paradigm of behavioral science through the deep integration of multiple technology stacks. From the detailed analysis of individual behaviors to the study of complex interactions within groups, and from the description of basic behavioral characteristics to the causal inference of cognitive mechanisms, this technological system demonstrates powerful methodological innovation capabilities. With the continuous integration of cutting-edge technologies such as brain-like computing and quantum sensing, the panoramic recording cabin will drive animal behavior research towards both more microscopic neural mechanism analysis and more macroscopic ecological behavior simulation, providing crucial technological support for basic life science research.
[0037] Please see Figure 1 - Figure 8This utility model provides an embodiment of a behavior observation panoramic recording cabin, including a support frame 1, a door panel 4 rotatably connected to the support frame 1 via a rotating component, a viewing glass 5 fixedly connected to the inside of the support frame 1, a recording component disposed inside the support frame 1, a humidity sensor 21 fixedly connected to the inside of the viewing glass 5, a temperature sensor 22 fixedly connected to the inside of the viewing glass 5, a rigid tube 24 rotatably connected to the inside of the support frame 1, an atomizing nozzle 25 fixedly connected to the rigid tube 24, a universal joint 26 fixedly connected to the support frame 1, a connecting hose 27 fixedly connected to the side of the universal joint 26 away from the rigid tube 24, a rotating rod 28 rotatably connected to the inside of the support frame 1, a fan 29 fixedly connected to the inside of the rotating rod 28, a fixed frame 210 fixedly connected to the fan 29, and a heating tube 211 fixedly connected to the inside of the fixed frame 210. The rigid tube 24 is disposed on the universal joint 26, allowing observation of the interior of the support frame 1 through the viewing glass 5, and enabling observation of the interior of the device through the recording component. Animal monitoring and recording are performed using humidity sensor 21 and temperature sensor 22 to detect the temperature and humidity inside the recording chamber. When the temperature is low, air heated by heating tube 211 is blown into the recording chamber, and fan 29 rotates back and forth to increase the airflow range of fan 29, thus improving the uniformity of temperature rise inside the recording chamber. When the recording chamber is relatively dry, atomized water is sprayed into the recording chamber through atomizing nozzle 25, and the atomizing nozzle 25 rotates back and forth to increase the spray range of atomizing nozzle 25, making it easier to control the temperature and humidity inside the recording chamber, improving the ability to regulate the temperature and humidity inside the recording chamber, improving the reliability of behavioral recording data, and improving the practicality of the device. The recording component slides on the fixed frame 37 via spherical frame 38 to adjust the horizontal angle of camera 311, and slides on the spherical frame 38 via movable frame 39 to adjust the vertical angle of camera 311, thus facilitating shooting while following the animal's movement and improving the recording effect of the animal.
[0038] Please see Figure 2 - Figure 5In this embodiment, the viewing glass 5 has ventilation slots for air circulation, and two sets of ventilation slots are symmetrically distributed on the viewing glass 5. This facilitates the circulation of oxygen inside the recording chamber, improving the animal's comfort and enhancing the accuracy of observation and recording of animal behavior. An illumination lamp 23 is fixedly connected to the inner side of the viewing glass 5 to illuminate the interior of the device. A gear 212 is fixedly connected to the rotating rod 28 and to the rigid tube 24. A toothed plate is slidably connected inside the support frame 1. 213, gear 212 meshes with the outside of gear plate 213, a connecting block 214 is fixedly connected to the bottom of gear plate 213, a hydraulic telescopic rod 215 is fixedly connected to the support frame 1, and the connecting block 214 is fixedly connected to the telescopic end of hydraulic telescopic rod 215. Humidity sensor 21 and temperature sensor 22 detect the temperature and humidity inside the recording chamber. When the temperature is low, the air heated by heating tube 211 is blown into the recording chamber, and then the fan 29 reciprocates, thereby increasing the airflow range of fan 29. To improve the uniformity of temperature rise inside the recording chamber, when the inside of the recording chamber is relatively dry, atomizing water is sprayed into the recording chamber through the atomizing nozzle 25. The reciprocating rotation of the atomizing nozzle 25 increases the spray range, facilitating control of temperature and humidity inside the recording chamber, improving the ability to regulate temperature and humidity, enhancing the reliability of behavioral recording data, and improving the practicality of the device. Two sets of gears 212, gear plate 213, connecting block 214, and hydraulic telescopic rod 215 are all provided. Two sets of gears 212, gear plates 213, connecting blocks 214, and hydraulic telescopic rods 215 are sequentially distributed at corresponding positions on the rotating rod 28 and the rigid tube 24, allowing them to control the rotating rod 28 and the rigid tube 24 on both sides individually, thereby improving the control effect on the temperature and humidity inside the recording chamber. The support frame 1 has a matching limiting groove at the corresponding position of the gear plate 213, and the gear plate 213 slides in the limiting groove of the support frame 1, thereby limiting the gear plate 213 and improving the reciprocating rotation stability of the rigid tube 24 and the rotating rod 28.
[0039] Please see Figure 6 - Figure 8In this embodiment, the recording component includes a PLC controller 31 fixedly connected to the inner wall of the support frame 1, a mounting frame 32 fixedly connected to the inner wall of the support frame 1, a first motor 33 fixedly connected to the mounting frame 32, a first rotating bracket 34 fixedly connected to the output end of the first motor 33, a second motor 35 fixedly connected to the mounting frame 32, a second rotating bracket 36 fixedly connected to the output end of the second motor 35, a fixed frame 37 fixedly connected to the mounting frame 32, a spherical frame 38 slidably connected to the fixed frame 37, a movable frame 39 slidably connected to the spherical frame 38, and a fixed... A support rod 310 is connected to the movable frame 39; a camera 311 is fixedly connected to the end of the support rod 310 away from the movable frame 39; a photoelectric sensor 312 is fixedly connected to the camera 311; a second rotating bracket 36 is rotatably connected inside the mounting frame 32; a second motor 35 is electrically connected to the PLC controller 31; a first rotating bracket 34 is rotatably connected inside the mounting frame 32; a first motor 33 is electrically connected to the PLC controller 31; the support rod 310 is disposed inside the first rotating bracket 34; the support rod 310 is disposed in the groove of the second rotating bracket 36; and a recording component is also included. The spherical frame 38 slides on the fixed frame 37 to adjust the horizontal angle of the camera 311, and the movable frame 39 slides on the spherical frame 38 to adjust the vertical angle of the camera 311. This facilitates filming while following animal movements, improving the recording effect. The spherical frame 38 has a corresponding limiting groove at a corresponding position on the fixed frame 37, and the fixed frame 37 is positioned within the limiting groove of the spherical frame 38. Similarly, the spherical frame 38 has a corresponding limiting groove at a corresponding position on the movable frame 39, and the movable frame 39 slides within the limiting groove of the spherical frame 38, facilitating... The angles of the camera 311 and photoelectric sensor 312 are adjusted to allow them to easily follow the movement of the animal and adjust their own angles, thereby improving the practicality of the device. The first rotating bracket 34 has a matching through groove at the corresponding position of the support rod 310, and the support rod 310 is set inside the through groove of the first rotating bracket 34. The second rotating bracket 36 has a matching through groove at the corresponding position of the support rod 310, and the support rod 310 is set inside the through groove of the second rotating bracket 36. This improves the ease of adjusting the angles of the camera 311 and photoelectric sensor 312, thereby improving the practicality of the device.
[0040] During operation, the photoelectric sensor 312 (model E3Z-D61) detects the animal's position and transmits commands to the PLC controller 31. The PLC controller 31 then controls the switching of the first motor 33 and the second motor 35. Starting the first motor 33 causes the first rotating bracket 34 to rotate inside the mounting frame 32. A support rod 310, positioned inside the through slot of the first rotating bracket 34, causes the spherical frame 38 to slide on the fixed frame 37, adjusting the lateral angle of the camera 311. Starting the second motor 35 causes the second rotating bracket 36 to rotate inside the mounting frame 32. The camera 311 is moved by a support rod 310 located inside the through slot of the second rotating bracket 36, which drives the movable frame 39 to slide on the spherical frame 38 to adjust the vertical angle of the camera 311. This facilitates tracking the animal's movement and improves the recording effect, thus enhancing the practicality of the device. Humidity sensor 21 and temperature sensor 22 are used to sense and record the temperature and humidity inside the chamber. Humidity sensor 21 is a DHT11, and temperature sensor 22 is a CWDZ11. The working principles of the photoelectric sensor 312, humidity sensor 21, temperature sensor 22, PLC controller 31, first motor 33, and second motor 35 are common in this technical field. Using technical means, which will not be described in detail here, when the temperature is low, the heating tube 211 inside the fixed frame 210 is activated, and then the motor on the fan 29 is started, so that the air heated by the heating tube 211 is blown into the interior of the recording chamber. At this time, the hydraulic telescopic rod 215 at the rotating rod 28 is extended or retracted, which drives the toothed plate 213 to reciprocate inside the support frame 1. Through the gear 212 meshing with the outside of the toothed plate 213, it makes the rotating rod 28 rotate inside the support frame 1, thereby driving the fan 29 to reciprocate, thereby increasing the airflow range of the fan 29 and improving the uniformity of the temperature rise inside the recording chamber, thus facilitating the control of the recording chamber interior. When the temperature inside the recording chamber is relatively dry, the connecting hose 27 is connected to an external water pump, which draws water from the external source and allows it to enter the rigid pipe 24 through the connecting hose 27. The atomizing nozzle 25 then sprays atomized water into the recording chamber. At this time, the hydraulic telescopic rod 215 at the telescopic rigid pipe 24 drives the rigid pipe 24 to rotate inside the support frame 1. The universal adapter 26 prevents the connecting hose 27 from tangling when the rigid pipe 24 rotates, thereby causing the atomizing nozzle 25 to rotate back and forth, increasing the spray range of the atomizing nozzle 25, making it easier to control the humidity inside the recording chamber, and thus improving the animal's comfort.
[0041] Through the above steps, the humidity sensor 21 and temperature sensor 22 detect the temperature and humidity inside the recording chamber. When the temperature is low, the air heated by the heating tube 211 is blown into the recording chamber, and the fan 29 rotates back and forth to increase the airflow range of the fan 29, thereby improving the uniformity of temperature rise inside the recording chamber. When the recording chamber is relatively dry, the atomizing nozzle 25 sprays atomized water into the recording chamber. The atomizing nozzle 25 rotates back and forth to increase the spray range of the atomizing nozzle 25, making it easier to control the temperature and humidity inside the recording chamber. This improves the ability to regulate the temperature and humidity inside the recording chamber, thus solving the problem that the temperature and humidity environment inside the recording chamber lacks effective dynamic control capabilities, and that researchers cannot accurately set and maintain stable temperature and humidity parameters according to the physiological needs or behavioral research goals of animals, resulting in reduced reliability of experimental data.
Claims
1. A panoramic recording cabin for behavioral observation, including a support frame (1), characterized in that: It also includes a door panel (4) rotatably connected to the support frame (1) via a rotating component, a viewing glass (5) fixedly connected to the inside of the support frame (1), a recording component installed inside the support frame (1), a humidity sensor (21) fixedly connected to the inside of the viewing glass (5), a temperature sensor (22) fixedly connected to the inside of the viewing glass (5), a rigid tube (24) rotatably connected to the inside of the support frame (1), an atomizing nozzle (25) fixedly connected to the rigid tube (24), a universal adapter (26) fixedly connected to the support frame (1), and a universal adapter (26) fixedly connected to the universal adapter. The adapter (26) has a connecting hose (27) on the side away from the rigid tube (24), a rotating rod (28) rotatably connected inside the support frame (1), a fan (29) fixedly connected inside the rotating rod (28), a fixed frame (210) fixedly connected to the fan (29), and a heating tube (211) fixedly connected inside the fixed frame (210). The rigid tube (24) is set on the universal adapter (26). The inner cavity of the support frame (1) can be observed through the viewing glass (5), and the animal inside the device can be monitored and recorded through the recording component.
2. The behavior observation panoramic recording cabin according to claim 1, characterized in that: The viewing glass (5) has ventilation slots for ventilation, and there are two sets of ventilation slots, which are symmetrically distributed on the viewing glass (5).
3. The behavior observation panoramic recording cabin according to claim 1, characterized in that: An illumination lamp (23) for illuminating the inside of the device is fixedly connected to the inner side of the viewing glass (5). A gear (212) is fixedly connected to the rotating rod (28). The gear (212) is fixedly connected to the rigid tube (24). A toothed plate (213) is slidably connected inside the support frame (1). The gear (212) meshes with the outside of the toothed plate (213). A connecting block (214) is fixedly connected to the bottom of the toothed plate (213). A hydraulic telescopic rod (215) is fixedly connected to the support frame (1). The connecting block (214) is fixedly connected to the telescopic end of the hydraulic telescopic rod (215).
4. The behavior observation panoramic recording cabin according to claim 3, characterized in that: Two sets of gears (212), toothed plates (213), connecting blocks (214), and hydraulic telescopic rods (215) are provided. The two sets of gears (212), toothed plates (213), connecting blocks (214), and hydraulic telescopic rods (215) are distributed in the corresponding positions of the rotating rod (28) and the rigid tube (24).
5. The behavior observation panoramic recording cabin according to claim 3, characterized in that: The support frame (1) has a matching limiting groove at the corresponding position of the toothed plate (213), and the toothed plate (213) slides in the limiting groove of the support frame (1).
6. The behavior observation panoramic recording cabin according to claim 1, characterized in that: The recording assembly includes a PLC controller (31) fixedly connected to the inner wall of the support frame (1), a mounting frame (32) fixedly connected to the inner wall of the support frame (1), a first motor (33) fixedly connected to the mounting frame (32), a first rotating bracket (34) fixedly connected to the output end of the first motor (33), a second motor (35) fixedly connected to the mounting frame (32), a second rotating bracket (36) fixedly connected to the output end of the second motor (35), a fixed frame (37) fixedly connected to the mounting frame (32), a spherical frame (38) slidably connected to the fixed frame (37), a movable frame (39) slidably connected to the spherical frame (38), and a fixed frame (39) fixedly connected to the support frame (1). The movable frame (39) has a support rod (310), a camera (311) fixedly connected to the end of the support rod (310) away from the movable frame (39), a photoelectric sensor (312) fixedly connected to the camera (311), a second rotating bracket (36) rotatably connected to the inside of the mounting frame (32), a second motor (35) electrically connected to the PLC controller (31), a first rotating bracket (34) rotatably connected to the inside of the mounting frame (32), a first motor (33) electrically connected to the PLC controller (31), a support rod (310) set inside the first rotating bracket (34), and a support rod (310) set in the groove of the second rotating bracket (36).
7. The behavior observation panoramic recording cabin according to claim 6, characterized in that: The spherical frame (38) has a matching limiting groove at the corresponding position of the fixed frame (37). The fixed frame (37) is set in the limiting groove of the spherical frame (38), and the spherical frame (38) has a matching limiting groove at the corresponding position of the movable frame (39). The movable frame (39) slides in the limiting groove of the spherical frame (38).
8. The behavior observation panoramic recording cabin according to claim 6, characterized in that: The first rotating bracket (34) has a matching through groove at the corresponding position of the support rod (310), and the support rod (310) is located inside the through groove of the first rotating bracket (34). The second rotating bracket (36) has a matching through groove at the corresponding position of the support rod (310), and the support rod (310) is located inside the through groove of the second rotating bracket (36).