Description:FIELD OF THE INVENTION

[0001] The present invention relates to a camping tent system that is capable of enhancing user safety, adapt to environmental conditions, and provide comfort during outdoor activities through monitoring and responsive structural features.

BACKGROUND OF THE INVENTION

[0002] In recent years, the popularity of outdoor recreational activities such as camping, trekking, and wildlife expeditions has significantly increased. Alongside this growth, there has been a rising demand for tent systems that not only offer shelter but also ensure a high level of safety, convenience, and adaptability in unpredictable environments. Modern campers often face diverse challenges including varying terrain conditions, fluctuating weather, and potential threats from surrounding wildlife. As outdoor adventures become more immersive and prolonged, there is an increasing need for a tent system that can intelligently respond to these dynamic environmental conditions and user requirements, without constant manual intervention. The evolution of technology and smart systems has opened possibilities for enhancing traditional shelter to deliver proactive support, efficient control, and greater reliability in outdoor settings.

[0003] Traditionally, camping tents have relied on passive designs and static structures that provide limited response to external factors. These tents often require manual setup, adjustment, and monitoring, which may not be practical or safe in challenging terrains or during unexpected situations. While certain improvements have been made over the years such as lightweight materials, quick-fold frames, and basic weather protection, most available systems lack the capability to actively adapt or intelligently interact with their environment. Furthermore, conventional tent designs are generally not equipped to address sudden environmental shifts, user-specific needs, or safety threats that can arise during camping. As a result, there exists a need for a more advanced and responsive system that can elevate the safety, utility, and comfort standards expected by modern outdoor users.

[0004] CN217680929U discloses an intelligence tent especially relates to an intelligence tent with solar energy mosquito repellent function. The utility model provides an intelligent tent with solar energy mosquito repellent function that can carry out effective kill mosquito to the mosquito through the mosquito repellent lamp. The utility model provides an intelligence tent with solar energy mosquito repellent function, is equipped with two door curtains including tent, door curtain, rivet and solar energy mosquito repellent mechanism, the tent front side, and the tent bottom is equipped with the rivet, and the tent top is equipped with solar energy mosquito repellent mechanism. The tent is fixed on the ground through riveting pins, so that people can fix the tent conveniently.

[0005] CN109070788B discloses a camping assembly (2) may be in the form of a collapsible camper (10) and includes a canopy (30) effective to provide a tent canopy (30) for the collapsible camper (10). The collapsible camper (10) further includes a frame (32) to maintain the tent roof (30) in the raised configuration so that the collapsible camper (10) provides a containment space in the assembled configuration. The frame (32) includes a front frame (34) and a rear frame (36). The front frame (34) includes three air beams (41,42, 43). The present invention provides a collapsible camper (10) assembled by simultaneously inflating separate networks of air beams to place the canopy (30) in tension and to tighten the canopy (30), the invention provides a collapsible camper (10) that does not require any additional tensioning system or mechanism for the canopy, as this is through the connection around the lower edge of the canopy of the rail and because of the network of air beams, the rear frame (36) includes three air beams (45,46,47) each including a curved or looped inflatable air beam, likewise, the rear frame (36) includes three air beams (45,46,47), the three air beams (45,46,47) include a front air beam (45), a middle air beam (46), and a rear air beam (47). the invention provides a collapsible camper (10) assembled by simultaneously inflating separate networks of air beams to place the canopy (30) in tension and tighten the canopy (30) In particular the geometry of the central longitudinal air beam.

[0006] Conventionally, many systems have been designed for outdoor shelter, primarily focusing on providing basic protection against environmental elements such as wind, rain, and sunlight. These existing systems often lack the capability to adapt to dynamic surroundings or respond intelligently to user needs, and user safety from wild animals resulting in limited functionality and compromised safety in challenging outdoor conditions.

[0007] In order to overcome the aforementioned drawbacks, there exists a need in the art to develop a system that requires to offer enhanced adaptability, user safety, and intelligent responsiveness to environmental conditions, thereby ensuring a more secure, comfortable, and efficient camping experience in diverse and unpredictable outdoor settings.

OBJECTS OF THE INVENTION

[0008] The principal object of the present invention is to overcome the disadvantages of the prior art.

[0009] An object of the present invention is to develop a system that enhances safety, comfort, and usability for users in outdoor camping environments.

[0010] Another object of the present invention is to develop a system that intelligently adapts to varying environmental conditions and potential external threats.

[0011] Yet another object of the present invention is to develop a system that reduces manual intervention by automating essential functions of a camping tent for an improved outdoor living experience.

[0012] The foregoing and other objects, features, and advantages of the present invention will become readily apparent upon further review of the following detailed description of the preferred embodiment as illustrated in the accompanying drawings.

SUMMARY OF THE INVENTION

[0013] The present invention relates to a camping tent system that is capable of providing enhanced outdoor shelter through intelligent adaptability, user safety features, and responsive functionality based on surrounding environmental conditions.

[0014] According to an embodiment of the present invention, a camping tent system, comprises of a tent structure having a thermotropic covering sheet coupled with a Peltier unit to control transparency based on ambient lighting, a microcontroller linked with a database to manage and analyze sensor inputs, an infrared sensor and an AI-enabled camera configured to detect an animal approaching the tent, a first proximity sensor mounted on an outer side to confirm presence and distance of a nearby object, a bottom periphery having a plurality of cushion patches with internal pressure regulation and a plurality of ultrasonic sensors to detect and respond to uneven terrain, a plurality of top motorized rollers configured to deploy a metal chain curtain for protective reinforcement, each curtain being embedded with pneumatic earth anchors to secure the tent to the ground, a bottom motorized roller attached to a plurality of flexible mat units to form a stable and cushioned platform for a user, a light sensor positioned on an outer side of the tent structure to continuously monitor environmental brightness and operate the Peltier unit accordingly, a second proximity sensor mounted on an inner side to detect user movement and activate the mat deployment sequence, and an animal repelling unit configured to respond to detected threats using pre-programmed response sequences and external stimuli control.

[0015] According to another embodiment of the present invention, the system further comprises of a holographic unit mounted on an outer side to create large-scale 3D deterrent visuals, a sprinkler strategically attached and connected through a conduit to a pressurized water container to emit a sudden water burst, an imaging unit to process visual cues, a high-quality microphone configured to capture directional animal sounds, a directional speaker designed to emit focused and animal-specific repelling audio, a GPS module configured to capture real-time geographic location and transmit it to a linked smart device or emergency network, a database enabled with artificial intelligence to analyse combined inputs from visual, acoustic, and proximity sensors, the smart device interface such as a mobile phone or wearable allowing real-time system monitoring and manual override, a flexible mat constructed from a polyurethane outer surface, an EVA foam core, and a reinforcement mesh for structure and durability, and a covering sheet with thermotropic characteristics responsive to temperature changes controlled via internal heat modulation.

[0016] While the invention has been described and shown with particular reference to the preferred embodiment, it will be apparent that variations might be possible that would fall within the scope of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] These and other features, aspects, and advantages of the present invention will become better understood with regard to the following description, appended claims, and accompanying drawings where:
Figure 1 illustrates an isometric view of a camping tent system; and
Figure 2 illustrates an inner view of a camp associated with the system.

DETAILED DESCRIPTION OF THE INVENTION

[0018] The following description includes the preferred best mode of one embodiment of the present invention. It will be clear from this description of the invention that the invention is not limited to these illustrated embodiments but that the invention also includes a variety of modifications and embodiments thereto. Therefore, the present description should be seen as illustrative and not limiting. While the invention is susceptible to various modifications and alternative constructions, it should be understood, that there is no intention to limit the invention to the specific form disclosed, but, on the contrary, the invention is to cover all modifications, alternative constructions, and equivalents falling within the spirit and scope of the invention as defined in the claims.

[0019] In any embodiment described herein, the open-ended terms "comprising," "comprises,” and the like (which are synonymous with "including," "having” and "characterized by") may be replaced by the respective partially closed phrases "consisting essentially of," consists essentially of," and the like or the respective closed phrases "consisting of," "consists of, the like.

[0020] As used herein, the singular forms “a,” “an,” and “the” designate both the singular and the plural, unless expressly stated to designate the singular only.

[0021] The present invention relates to a camping tent system that is capable of offering an camping solution by responding to environmental changes, enhancing user safety from animals, and improving overall comfort. In addition, the system is also designed to operate efficiently in diverse outdoor conditions while minimizing the need for manual adjustments by the user.

[0022] Referring to Figure 1 and 2, illustrates an isometric view of a camping tent system and an inner view of a tent structure associated with the system are illustrated, respectively, comprising a tent structure 101 having a thermotropic covering sheet 102, an AI (Artificial Intelligence) enabled camera 103 attached on the tent structure 101, a plurality of top motorized rollers 104 attached on the top of the tent structure 101, the rollers 104 includes a metal chain curtain 104a free ends of which are attached with a plurality of pneumatic earth anchors 104b, an animal repelling unit 105 installed on the outer side of the tent structure 101, the animal repelling unit 105 comprises of a holographic unit 105a attached to the outer side of the tent structure 101, a plurality of sprinklers 105b attached to the outer side of the tent structure 101, an imaging unit 105c, a high-quality microphone 105d, and a direction speaker 105e mounted at the top portion of the tent structure 101, a water container 106 through a conduit 107 is connected to the sprinkler 105b, a plurality of cushion patches 201 integrated on the bottom periphery of the tent structure 101, a bottom motorized roller 202 coupled to a flexible mat 203 attached inside the tent structure 101, a hologram projector 204 integrated in the inner side of the tent structure 101.

[0023] The system disclose herein comprises of a tent structure 101 having a thermotropic covering sheet 102. The thermotropic covering sheet 102 internally consists of a specialized sheet 102 embedded with thermally responsive materials that alter their light transmission properties based on temperature. When exposed to a specific thermal range, these materials undergo a physical change, such as shifting from an ordered to a disordered state, which modifies the sheet’s transparency. This transition causes the sheet 102 to switch between translucent and opaque states, enabling dynamic light regulation within the enclosed space without the need for mechanical adjustment.

[0024] A light sensor attached to an outer side of the tent structure 101 for monitoring day and night and operably connected to a microcontroller. The microcontroller linked with a database integrated within the system which activates the light sensor. This sensor internally comprises a photodiode that converts incident light into an electrical signal. As ambient light levels change, the intensity of light striking the sensor alters the current output proportionally. This analog signal is then processed by an internal amplifier and, if necessary, digitized by an onboard ADC (analog-to-digital converter). The processed signal is sent to the microcontroller, which interprets it to determine environmental brightness.

[0025] When the microcontroller receives input from the light sensor indication a change in ambient light conditions, such as transition from day to night or vice versa, then the microcontroller activates a Peltier unit attached with the sheet 102 to the transparency of the sheet 102. The Peltier unit works on the thermoelectric effect, consisting of two different semiconductor materials arranged in a series of junctions between ceramic plates. When a direct current flows through the unit, electrons move from one material to another, causing heat to be absorbed on one side and released on the other. This creates a temperature differential across the unit. Internally, the direction and intensity of current determine which side cools or heats, enabling precise thermal regulation without moving parts or refrigerants.

[0026] An AI (Artificial Intelligence) enabled camera 103 with an infrared sensor attached on the tent structure 101 for animal detection. The AI enabled camera 103 internally consists of an image sensor (such as CMOS) that captures visual data, which is then processed by a neural processing unit (NPU). The captured frames are analysed using pre-trained machine learning models stored in embedded memory to identify patterns, objects, or animals. Internal protocols continuously run inference tasks to detect motion, classify entities, and assess threat levels. The camera 103 autonomously filters noise, adjusts focus and exposure, and transmits analysed results to the microcontroller for decision-making.

[0027] Complementing this functionality, the infrared sensor works by emitting infrared light and detecting the reflected radiation from nearby objects. Internally, it contains an emitter diode and a photodetector that senses changes in infrared intensity when an object enters its field. Variations in thermal radiation, especially from warm-blooded animals, cause detectable changes in the signal. These signals are processed by internal circuitry to determine presence or movement, and the output is relayed to the microcontroller to support or verify camera-based detection based on the predefined information from the database. The database stores historical data for all regions, variety of fauna and its details along with their predators’ details. The database is AI enabled database capable of processing collected data.

[0028] Further, a first proximity sensor mounted on the outer side of the tent structure 101 to provide real-time detection of animals or objects approaching the outer perimeter of the tent structure 101. The proximity sensor works by emitting an electromagnetic field and monitoring the reflection or disturbance caused by nearby objects. Internally, it contains a transmitter that emits a continuous wave and a receiver that detects changes in the reflected signal. When an animal enters the sensing range, the signal’s frequency, phase, or amplitude changes. This variation is processed by internal circuitry to calculate distance or presence. The resulting data is converted into an electrical signal and sent to the microcontroller.

[0029] If infrared sensor with AI enabled camera 103 in conjunction with the proximity sensor detects the animal, the microcontroller then actuates a plurality of top motorized rollers 104 attached to the tent structure 101. The rollers 104 includes a metal chain curtain 104a with two ends where one end is operably coupled to the rollers 104 and the second end is a free end and move over the covering material to reinforce the tent structure 101. The top motorized rollers 104 internally consist of an electric motor connected to a cylindrical shaft around which the metal chain curtain 104a is wound. When activated by the microcontroller, electrical power drives the motor, generating rotational motion through a gear means. An encoder monitors the roller’s position and speed for precise deployment. The motor’s direction determines whether the metal chain curtain 104a is deployed or retracted. Internal limit switches ensure controlled stopping points, preventing overextension or tangling of the curtain 104a during operation.

[0030] To facilitate the fixing of the metal chain to the ground, the microcontroller actuates a plurality of pneumatic earth anchors 104b attached to the free end of the metal chain curtain 104a to fix on the ground. The pneumatic earth anchors 104b work by using compressed air to drive anchoring rods into the ground. Internally, each anchor contains a sealed pneumatic chamber, a piston-cylinder assembly, and a deployable claw. When the microcontroller sends an electrical signal, a solenoid valve opens, allowing compressed air to enter the chamber. The pressurized air pushes the piston, which drives the anchor into the soil. Integrated sensors monitor deployment status. To retract, the airflow is reversed or vented, pulling the anchor back.

[0031] After deploying the metal chain curtain 104a the microcontroller activates an animal repelling unit 105 installed on the outer side of the tent structure 101. The animal repelling unit 105 operably connected to the AI enabled camera 103 and comprises a holographic unit 105a attached to the outer side of the tent structure 101 to create a holographic image for threatening visuals for the nearby animal. The holographic unit 105a works by projecting 3D (three-dimensional) images using light diffraction techniques. Internally, it comprises a laser light source, beam splitters, spatial light modulators (SLMs), and a projection surface. The SLM modulates the light wavefront based on digitally stored holographic data from the database, creating interference patterns. These patterns are then directed through optical lenses to reconstruct a 3D visual in space. The internal processor synchronizes image generation with input commands, enabling the unit to display dynamic, realistic visuals that appear to float or move around the tent.

[0032] To repel the nearby animal, the microcontroller works in conjunction with the AI enabled camera 103 and actuates a plurality of sprinklers 105b attached to the outer side of the tent structure 101 for spraying water on them. The sprinkler 105b works by channelling pressurized water through a nozzle to generate a directed spray. Internally, it includes a solenoid valve, which regulates the water flow, and a nozzle assembly that shapes and disperses the water stream. When an electrical signal is received by the microcontroller, the solenoid valve opens, allowing water to pass through the internal chamber and exit via the nozzle. The nozzle produces a mist or a burst depending on the pressure, enabling effective area coverage.

[0033] This water is supplied from a dedicated water container 106 connected through a conduit 107. Internally, the water container 106 is a sealed reservoir equipped with a pressure regulation unit and a fluid-level sensor. The conduit 107 is a flexible tube that forms a continuous sealed path from the container 106 to the sprinklers 105b inlet. When activated by the microcontroller, the pressure regulator in the container 106 ensures consistent water flow through the conduit 107, allowing the sprinklers 105b to operate efficiently without manual intervention.

[0034] Furthermore, the animal repelling unit 105 comprises an imaging unit 105c, a high-quality microphone 105d, and a directional speaker 105e. The imaging unit 105c functions as a visual detection module, internally comprising a high-resolution lens, a CMOS sensor, and an onboard image processor. When light enters the lens, it is focused onto the sensor, which converts the light into digital signals. These signals are processed to extract visual patterns, motion, and shape recognition. The processed data is then relayed to the microcontroller and also synchronized with audio inputs from the microphone 105d, enabling precise identification and tracking of nearby animals.

[0035] The high-quality microphone 105d operates as an acoustic sensing component, internally consisting of a diaphragm, a backplate, and an amplifier circuit. When animal sound waves reach the diaphragm, it vibrates, creating a varying capacitance between the diaphragm and backplate. This variation is converted into an electrical signal and amplified internally. The processed audio is analysed in conjunction with the imaging data to determine the type and direction of the detected animal, enhancing system accuracy for targeted deterrence through the directional speaker 105e.

[0036] The directional speaker 105e converts electrical audio signals into focused sound waves, allowing targeted sonic deterrence. Internally, it features a phased array of transducers that use constructive and destructive interference to steer sound in a specific direction. The microcontroller uses input from the imaging unit 105c and microphone 105d to calculate the exact angle and distance of the target. Based on this, the speaker 105e emits specific frequencies or animal-specific repelling sounds, ensuring minimal disturbance to the surrounding environment while effectively targeting the detected threat.

[0037] Inside the tent structure 101, a plurality of cushion patches 201 mounted at bottom periphery to provide cushioning effect to the tent structure 101 base. The plurality of cushion patches 201 works as adaptive ground contact modules designed to stabilize and level the tent base. Internally, each patch contains a flexible air bladder, a mini air pump, and a pressure control valve. When activated by the microcontroller, the air pump inflates or deflates the bladder to adjust its thickness, compensating for ground unevenness. The microcontroller regulates inflation levels based on data received from a plurality of ultrasonic sensors, ensuring uniform support. The cushion patches 201 enhance comfort and structural balance, especially on rough or sloped terrain.

[0038] The plurality of ultrasonic sensors functions as ground-surface detection unit. Internally, each sensor contains a piezoelectric transducer that emits ultrasonic sound waves toward the ground. When these waves reflect back, the sensor measures the time delay to calculate the distance to the surface. This time-of-flight data helps identify variations in ground height beneath the tent. The processed information is relayed to the microcontroller, which adjusts the inflation of the nearby cushion patches 201, enabling real-time terrain-adaptive positioning of the tent base.

[0039] In order to make a platform for the user, the microcontroller actuates a bottom motorized roller 202 attached at the base of the tent structure 101 and coupled to a flexible mat 203 to deploy or retract the mat 203 to lay the platform for the user. The bottom motorized roller 202 works internally in the similar manner as the top motorized rollers 104 operates. The flexible mat 203 functions as a deployable floor platform, providing comfort and insulation inside the tent. Internally, it is constructed from multiple layers including an anti-slip polyurethane outer layer, a memory foam or EVA (ethylene-vinyl acetate) middle layer for cushioning, and a flexible reinforcement mesh for durability.

[0040] Furthermore, a second proximity sensor attached to an inner side of the tent structure 101 for controlling the bottom motorized roller 202 to deploy or retract the mat 203. The second proximity sensor comprises an infrared emitter and receiver. When the user enters the sensing range, the reflected signal or electrical field disturbance is detected, indicating proximity. The sensor processes this variation and sends a corresponding signal to the microcontroller. This input is used to trigger the deployment or retraction of the flexible mat 203, ensuring automatic response to occupant presence.

[0041] Additionally, a hologram projector 204 integrated in the inner side of the tent structure 101 to present real-time visual guidance to the user. The hologram projector 204 works by generating 3D visual images using light wave manipulation. Internally, it includes a laser or high-intensity LED light source, beam splitters, spatial light modulators (SLMs), and a projection surface. The SLM modulates light based on pre-programmed holographic interference patterns, reconstructing images that appear three-dimensional to the viewer. An onboard processor controls real-time rendering, adjusting visuals according to user input or environmental data, allowing dynamic guidance or immersive feedback inside the tent space.

[0042] A GPS (Global Positioning System) module is attached to the tent structure 101 to share a real-time location to a database. The microcontroller activates the GPS module, when location tracking is required, such as during setup, emergency situations, or periodic status updates. Internally, it contains a GPS chip with a radio frequency (RF) receiver and signal processor. The receiver captures satellite signals and calculates the time delay from multiple satellites to determine precise geographic coordinates using trilateration. The onboard processor processes this data and converts it into latitude, longitude, and altitude. This location information is then relayed to the microcontroller for storage, analysis, or transmission to a connected database and device.

[0043] The microcontroller linked with the database is operably connectable with a smart device via wireless communication protocols such as Bluetooth, or Wi-Fi. Internally, the microcontroller contains a communication module and firmware that enable device discovery, pairing, and secure data exchange. Upon establishing a connection, it transmits system status, alerts, or environmental data to the smart device. For example, a smartphone or smartwatch receive notifications, allow manual control, or display real-time visuals from the tent through a dedicated mobile application.

[0044] The present invention works best in the following manner, where the tent structure 101 as disclosed in the invention is set up by the user on the selected camping ground. The thermotropic covering sheet 102 integrated into the tent structure 101 dynamically changes its transparency, wherein the light sensor installed on the outer side continuously monitors ambient lighting and relays input to the microcontroller, which activates the Peltier unit to adjust the temperature of the sheet 102, allowing light modulation for enhanced comfort and privacy. The infrared sensor in conjunction with the AI-enabled camera 103 mounted on the tent structure 101 continuously scans the surroundings to detect the presence of the animal, if detection is confirmed, the microcontroller processes the data and actuates the top motorized roller 104 to deploy the metal chain curtain 104a embedded with pneumatic earth anchors 104b that extend into the ground to reinforce the tent. Simultaneously, the animal repelling unit 105 installed on the outer side is activated, wherein the holographic unit 105a projects the deterrent 3D visual, the sprinkler 105b emits a sudden burst of water sourced from the water container 106 via the conduit 107, and the directional speaker 105e releases animal-specific repelling sound. If acoustic signals are detected via the high-quality microphone 105d, the microcontroller further refines the deterrent response using data from the imaging unit 105c. When the user enters the tent, the bottom periphery comprising the plurality of cushion patches 201 adjusts itself to uneven terrain based on real-time feedback from the plurality of ultrasonic sensors. The second proximity sensor installed on the inner side detects movement of the user and signals the microcontroller to activate the bottom motorized roller 202, which deploys the flexible mat 203 to provide the stable and comfortable floor. The GPS module periodically transmits the location of the tent to the connected database for safety monitoring. The microcontroller is operably connectable with a smart device such as a smartphone or smartwatch, enabling real-time control and data access through a dedicated interface application, ensuring seamless integration and user convenience throughout the operation.

[0045] Although the field of the invention has been described herein with limited reference to specific embodiments, this description is not meant to be construed in a limiting sense. Various modifications of the disclosed embodiments, as well as alternate embodiments of the invention, will become apparent to persons skilled in the art upon reference to the description of the invention. , C , Claims:1) A camping tent system, comprises:

i) a tent structure 101, having a thermotropic covering sheet 102 coupled to the tent structure 101, wherein the sheet 102 is attached with a Peltier unit to change the transparency of the sheet 102;
ii) a microcontroller with a linked database disposed in the system;
iii) an infrared sensor with an AI enabled camera 103 attached on the tent structure 101 and operably connected to the microcontroller to detect an animal;
iv) a first proximity sensor mounted on the outer side of the tent structure 101, and operably connected to the microcontroller, to detect the animal;
v) a bottom periphery of the tent structure 101 having:
a. plurality of cushion patches 201 to provide cushioning effect to tent structure 101,
b. plurality of ultrasonic sensors operably connected to the microcontroller to operate the cushion patches 201, if an unevenness of a ground on which the tent structure 101 is installed, is detected;
vi) plurality of top motorized rollers 104 attached to the tent structure 101, and operably connected to the microcontroller, the rollers 104 includes:
a. a metal chain curtain 104a with two ends, wherein one end is operably coupled to the rollers 104, and second end is a free end and moves over the covering material to reinforce the tent,
b. plurality of pneumatic earth anchors 104b attached to the free end to facilitate the fixing of the metal chain curtain 104a to the ground;
vii) a bottom motorized roller 202 attached to the tent structure 101, and operably coupled to a plurality of flexible mat 203 to deploy and/or retract said mat 203 to lay a platform for a user;
viii) a light sensor attached to an outer side of the tent structure 101 for monitoring day and night, and operably connected to the microcontroller for operating the Peltier unit to change the transparency of the sheet 102;
ix) a second proximity sensor attached to an inner side of the tent structure 101, and operably connected to the microcontroller for controlling the bottom motorized roller 202 to deploy and/or retract said mat 203 to lay a platform for a user; and
x) an animal repelling unit 105 is installed on the outer side of the tent structure 101, and operably connected to the microcontroller linked with a database, and gets activated if the dangerous animal is detected.

2) The system as claimed in claim 1, wherein the microcontroller linked with the database is operably connectable with a smart device.

3) The system as claimed in claim 1, wherein the database is AI enabled database capable of processing collected data.

4) The system as claimed in claim 1, wherein the inner side of the tent structure 101 is integrated to a hologram projector 204 to present real-time visual guidance to the user.

5) The system as claimed in claim 1, wherein the top motorized rollers 104 deploys the metal curtain 104a chain to reinforce the tent, if infrared sensor with AI enabled camera 103 in conjunction with the proximity sensor detects the animal.

6) The system as claimed in claim 1, wherein the animal repelling unit 105 is operated by the microcontroller and operably connected to the AI enabled camera 103, and the proximity sensor, the unit comprises:
a) a holographic unit 105a attached to the outer side of the tent structure 101 to create a holographic image to threatening visuals for the nearby animal; and
b) plurality of sprinklers 105b strategically attached to the outer side of the tent structure 101, and operated by the microcontroller in conjunction with the AI enabled camera 103, wherein the sprinkler 105b is triggered to release a sudden burst of water to repel the nearby animal.

7) The system as claimed in claim 5, wherein the sprinkler 105b is connected to a water container 106 through a conduit 107.

8) The system as claimed in claim 6, wherein the animal repelling unit 105 comprises of an imaging unit 105c, a high-quality microphone 105d, and a directional speaker 105e, wherein if said imaging unit 105c and the microphone 105d detects the animal, the directional speaker 105e activates a sound-based repulsion.

9) The system as claimed in claim 1, wherein the directional speaker 105e emits animal-specific sound in a targeted direction to repel the animal.

10) The system as claimed in claim 1, wherein the tent structure 101 is attached to a GPS module to share a real-time location to a database.