Description:FORM 2
THE PATENT ACT, 1970
(39 of 1970)
&
The Patent Rules, 2003
COMPLETE SPECIFICATION
(See section 10 and rule 13)
1. TITLE OF THE INVENTION:
A MULTI-LAYER INSULATED TENT WITH AN INTEGRATED THREE-IN-ONE HEATING SYSTEM
2. APPLICANT:
Name: ENERTECH BUILDING SOLUTIONS PRIVATE LIMITED
Nationality: Indian Company
Address: Plot No.66 to 77, Cherlapally, Indistrial Park, Phase-III, Hyderabad-500051, Telangana, India
3. PREAMBLE TO THE DESCRIPTION:
The following specification particularly describes the invention and the manner in which it is to be performed:

4. DESCRIPTION:
Field of the invention:
[0001] The present invention relates to the technical field of outdoor camping equipment, and more particularly, to a high-altitude a multi-layer insulated tent with an integrated three-in-one heating system that offers superior thermal insulation capabilities for effective heat retention in extreme cold weather conditions.
Background of the invention:
[0002] Arctic exploration and high-altitude mountaineering activities necessitate specialized equipment that can withstand extreme weather conditions. Shelters used in these environments require exceptional insulation properties to retain heat and protect occupants from sub-zero temperatures, wind, and precipitation

[0003] Traditional tents often rely on a single or double-layer fabric construction, which may not provide sufficient insulation for prolonged stays in frigid environments. Additionally, these tents frequently lack integrated three-in-one heating systems, forcing users to rely on bulky and potentially hazardous portable heaters.

[0004] Existing portable heating solutions for tents can be inefficient, unreliable, or pose safety risks. Fuel-powered heaters, for example, require continuous refilling and can create a risk of carbon monoxide poisoning if not properly ventilated. Electrical three-in-one heating systems often necessitate bulky and heavy external power sources, limiting portability and practicality in remote locations.

[0005] Furthermore, conventional tent designs may not adequately address ventilation needs. Condensation buildup within the tent can become a significant issue, leading to discomfort and potentially creating conditions for mold or mildew growth. Additionally, limited ventilation options can restrict fresh air circulation, impacting air quality and occupant well-being.

[0006] By addressing all the above-mentioned problems, there is a need for a high-altitude and multi-layer insulated tent that offers superior insulation capabilities to retain heat effectively in extreme cold conditions. There is also a need for a high-altitude tent with an integrated three-in-one heating system that eliminates the reliance on separate, potentially hazardous, portable heaters. Further, there is also a need for a high-altitude tent that improves ventilation strategies to address condensation issues and provides adequate fresh air circulation for a comfortable and healthy living environment for users in harsh arctic or high-altitude conditions.
Objectives of the invention:
[0007] The primary objective of the present invention is to provide a multi-layer insulated tent that offers superior thermal insulation capabilities for effective heat retention in extreme cold weather conditions.

[0008] Another objective of the present invention is to provide a multi-layer insulated tent that integrates a three-in-one heating system within the tent structure, which provides a safe and reliable source of heat for occupants.

[0009] Another objective of the present invention is to provide a multi-layer insulated tent that provides proper ventilation and adequate fresh air circulation to create a comfortable and healthy living environment for users.

[0010] Another objective of the present invention is to provide a multi-layer insulated tent that integrates a convection-cum-conduction three-in-one heating system for providing space heating, cooking, and boiling hot water with suitable capacity.

[0011] Another objective of the present invention is to provide a multi-layer insulated tent that provides internal, external, and intermediate fabric layers made out of polyester, waterproof, tear-free material to resist the formation of fungus or algae, a mosquito mesh having a zip to allow air ventilation, and a polymer insulation material that is able to withstand the harsh weather conditions of sub-zero temperatures.

[0012] Another objective of the present invention is to provide a multi-layer insulated tent that is constructed with a framework design that has lightweight, high-strength, high-tensile aluminum alloy tubular sections and provides modular, collapsible, and interlock able facilities.

[0013] Another objective of the present invention is to provide a multi-layer insulated tent that is user-friendly, lightweight, and portable.

[0014] Yet another objective of the present invention is to provide a multi-layer insulated tent that is made with robust construction techniques and high-quality waterproof and tear-resistant materials to improve the durability and weather resistance of the tent.

[0015] Further objective of the present invention is to provide a multi-layer insulated tent that offers a safe, comfortable, and reliable shelter for users engaged in exploration, mountaineering, or other activities in extreme cold weather environments.
Summary of the invention:
[0016] The present disclosure proposes a highly insulated tent with an integrated three-in-one heating system. The following presents a simplified summary in order to provide a basic understanding of some aspects of the claimed subject matter. This summary is not an extensive overview. It is not intended to identify key/critical elements or to delineate the scope of the claimed subject matter. Its sole purpose is to present some concepts in a simplified form as a prelude to the more detailed description that is presented later.

[0017] In order to overcome the above deficiencies of the prior art, the present disclosure is to solve the technical problem to provide a high-altitude and multi-layer insulated tent that offers superior thermal insulation capabilities for effective heat retention in extreme cold weather conditions.

[0018] According to an aspect, the invention relates to a high altitude and multi-layer insulated tent with an integrated three-in-one heating system. The tent is specifically designed to withstand harsh weather conditions encountered in high altitude and arctic environments. The high-altitude and multi-layer insulated tent with an integrated three-in-one heating system eliminates the reliance on separate, potentially hazardous, portable heaters. The high-altitude and multi-layer insulated tent improves ventilation strategies to address condensation issues and provides adequate fresh air circulation for a comfortable and healthy living environment for users in harsh arctic or high-altitude conditions.

[0019] In one embodiment herein, the multi-layer insulated tent comprises a collapsible frame unit made of flexible tubes that can be detachably connected to form a structure with side walls. This frame unit supports a tent fabric that defines an interior space for users. The tent fabric includes multiple layers, featuring a waterproof and tear-resistant outer layer, an inner layer, and intermediate layers with special insulation properties. This insulation, made of a polymer material, is designed to retain heat effectively inside the tent for extended periods.

[0020] The overall design of the multi-layer insulated tent prioritizes both functionality and user comfort. The lightweight, high-strength frame unit made of aluminum alloy tubes is modular, collapsible, and interlockable, making it easy to transport and assemble. Additionally, the tent fabric is made of a durable polyester material that is waterproof, tear-resistant, and resistant to fungus or algae growth, ensuring suitability for harsh weather conditions, including sub-zero temperatures.

[0021] In one embodiment herein, the multi-layer insulated tent also comprises a detachable tent floor that connects to the side walls of the frame unit to prevent air ingress from below. Access to the interior space is provided through a swing-type door equipped with a zipper and mosquito mesh for ventilation.

[0022] In one embodiment herein, an additional flap is provided on the outside of the multi-layer insulated tent, which protects the zipper from harsh weather conditions. The multi-layer insulated tent incorporates a locking unit on the flap for allowing the users to open and close the multi-layer insulated tent from the inside. For added comfort and visibility, the multi-layer insulated tent incorporates multiple windows with mosquito mesh. These windows allow users to see outside while keeping insects out.

[0023] The key feature of this invention is the integrated three-in-one heating system. Positioned within the multi-layer insulated tent, this system utilizes both convection and conduction methods to heat the interior space. Additionally, the three-in-one heating system can be used for cooking food and providing hot water through a heater powered by a burner.

[0024] In one embodiment herein, the three-in-one heating system comprises a fuel tank that stores fuel for the burner. In one embodiment herein, the heating system also comprises a regulator that controls the oxygen flow to the burner for efficient combustion.

[0025] In one embodiment herein, the three-in-one heating system also comprises an air blower that circulates warm air throughout the multi-layer insulated tent, thereby ensuring even heat distribution. In one embodiment herein, the three-in-one heating system also comprises a controller that manages the system's operation for optimal performance, safety, and user convenience. In one embodiment herein, the three-in-one heating system further comprises a power source that provides the necessary energy to run the system.

[0026] Further, objects and advantages of the present invention will be apparent from a study of the following portion of the specification, the claims, and the attached drawings.
Detailed description of drawings:
[0027] The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate an embodiment of the invention, and, together with the description, explain the principles of the invention.

[0028] FIG. 1 illustrates a schematic view of a multi-layer insulated tent, in accordance to an exemplary embodiment of the invention.

[0029] FIG. 2A illustrates an isometric front view of the multi-layer insulated tent, in accordance to an exemplary embodiment of the invention.

[0030] FIG. 2B illustrates an isometric rear view of the multi-layer insulated tent, in accordance to an exemplary embodiment of the invention.

[0031] FIG. 3 illustrates a perspective top view of the multi-layer insulated tent with a three-in-one heating system, in accordance to an exemplary embodiment of the invention.

[0032] FIG. 4 illustrates a block diagram of the three-in-one heating system, in accordance to an exemplary embodiment of the invention.

[0033] FIG. 5 illustrates an isometric front view of a multi-layer insulated tent for accommodating more users, in accordance to an exemplary embodiment of the invention.
Detailed invention disclosure:
[0034] Various embodiments of the present invention will be described in reference to the accompanying drawings. Wherever possible, same or similar reference numerals are used in the drawings and the description to refer to the same or like parts or steps.

[0035] The present disclosure has been made with a view towards solving the problem with the prior art described above, and it is an object of the present invention to provide a high-altitude insulated tent that offers superior thermal insulation capabilities for effective heat retention in extreme cold weather conditions.

[0036] According to an exemplary embodiment of the invention, FIG. 1 refers to a perspective view of a high altitude insulated tent with an integrated three-in-one heating system 118. The tent is specifically designed to withstand harsh weather conditions encountered in high altitude and arctic environments. The high-altitude tent with an integrated three-in-one heating system eliminates the reliance on separate, potentially hazardous, portable heaters. The high-altitude tent improves ventilation strategies to address condensation issues and provides adequate fresh air circulation for a comfortable and healthy living environment for users in harsh arctic or high-altitude conditions.

[0037] In one embodiment herein, the multi-layer insulated tent 100 comprises a frame unit 102 that is collapsible and constructed from flexible tubes 104. These flexible tubes 104 can be detachably connected to form a stable structure with side walls 108. The collapsible nature of the frame unit 102 allows the multi-layer insulated tent 100 to be packed down to a smaller size, making it easier to transport and carry, especially on expeditions where weight and space are limited. The detachable connections utilize a user-friendly mechanism, allowing for quick and easy assembly of the frame unit 102 without requiring complex tools. This expedites setup time and allows users to focus on enjoying their surroundings. Despite its collapsible nature, the frame unit 102 is designed to be strong and stable. The flexible tubes 104 can be made from a lightweight yet robust material like high-strength aluminum or composite materials. This ensures the frame unit 102 can withstand wind, snow load, and other potential stresses encountered in arctic environments.

[0038] The frame unit 102 supports a tent fabric 106 that defines an interior space for users. The tent fabric 106 includes multiple layers, featuring a waterproof and tear-resistant outer layer, an inner layer, and intermediate layers with special insulation properties. The outermost layer of the multi-layer insulated tent 100 is an external fabric layer constructed from waterproof, tear-free polyester. This robust material serves as the initial line of defense against the harsh elements. Its waterproof nature ensures that rain, snow, or meltwater doesn't penetrate the tent interior, keeping occupants dry and comfortable. Additionally, the tear-resistant property enhances the tent's overall durability against accidental rips or punctures that could compromise its weatherproofing capabilities. Furthermore, the polyester material is specifically chosen for its resistance to fungus and algae formation. This is particularly important in humid environments where organic growth on tent surfaces can be a concern.

[0039] Beneath the external fabric layer lies at least two intermediate fabric layers. These layers are also fabricated from polyester, which is chosen for its lightweight properties and ability to further enhance insulation. However, unlike the external layer, these intermediate layers may have specific properties depending on the desired functionality. For example, one layer could be treated with a reflective coating to reflect radiant heat back into the multi-layer insulated tent 100, thereby improving overall thermal efficiency. Another layer might be infused with a water-resistant treatment to provide additional protection against moisture penetration in case the outer layer experiences wear and tear.

[0040] In one embodiment herein, an innermost layer of the multi-layer insulated tent 100 is an internal fabric layer made of polyester. This layer provides a comfortable and breathable surface for the users. Polyester is a good choice for this application due to its breathability, allowing for some air circulation while still maintaining warmth. Additionally, it is relatively soft and pleasant to touch, thereby enhancing the overall comfort within the multi-layer insulated tent 100.

[0041] In one embodiment herein, a layer of polymer insulation material is configured for separating all the fabric layers. This material is specifically chosen for its exceptional ability to withstand sub-zero temperatures. Common insulation materials used in tents include down, synthetic insulation, or a combination of both. The specific type of polymer insulation used in the proposed multi-layer insulated tent 100 would be optimized for weight, heat retention, and moisture resistance, thereby ensuring excellent performance even in extreme arctic environments.

[0042] According to an exemplary embodiment of the invention, FIGs. 2A-2B refers to isometric front and rear views of the multi-layer insulated tent 100, respectively. In one embodiment herein, the multi-layer insulated tent 100 comprises a tent floor 110, which is a high-quality tarpaulin fabricated from a durable and waterproof material commonly used for outdoor applications. This choice ensures the tent floor 110 effectively prevents moisture from seeping up from the ground, thereby keeping the tent interior dry and comfortable. Additionally, the tent floor 110 is designed to be detachable from the side walls 108. This allows for easy cleaning and maintenance, as the tent floor 110 can be removed and washed separately. Furthermore, the detachable design facilitates thorough drying, thereby preventing moisture build-up and potential mold growth underneath the multi-layer insulated tent 100.

[0043] Most importantly, the tent floor 110 creates a complete seal at the connection point with the side walls 108. This seal prevents air ingress from below, thereby minimizing drafts and heat loss from the tent interior. This feature is particularly crucial in cold environments where maintaining warmth is essential for occupant comfort and safety. In one embodiment herein, the frame unit 102 is designed to accommodate attachment points for guy ropes 109, which are typically constructed from durable nylon. The guy ropes 109 are secured to anchor pegs 111 driven into ground. The guy ropes 109 provide additional stability to the tent structure, particularly in windy conditions, by distributing tension across the frame and preventing the tent from collapsing.

[0044] In one embodiment herein, the multi-layer insulated tent 100 incorporates a swing-type door 112 for user convenience. This type of swing-type door 112 allows for easy access to the tent interior, especially compared to traditional tent designs with zippers that require maneuvering from a kneeling or crouching position. The swing-type door 112 opens outwards, creating a wider entry point for bringing in gear or entering the tent comfortably. The swing-type door 112 is equipped with a zipper closure to provide a secure seal when closed. This zipper closure ensures that wind, rain, or snow doesn't enter the tent through the doorway. Additionally, the swing-type door 112 incorporates a mosquito mesh. This mesh allows for ventilation, promoting fresh air circulation within the tent while simultaneously preventing the entry of insects and mosquitoes. This dual benefit ensures a comfortable and healthy environment for the users, thereby especially during warmer weather conditions.

[0045] In one embodiment herein, the multi-layer insulated tent 100 comprises a flap 114 that is positioned on the outside of the multi-layer insulated tent 100. This strategic placement offers protection for the zipper of the door or window. The zippers are susceptible to damage from exposure to harsh weather elements like rain, snow, or ice build-up. The flap 114 acts as a protective barrier, shielding the zipper from these elements and preventing potential malfunction or corrosion. This ensures the zipper remains functional and allows for smooth opening and closing of the door or window. Furthermore, the flap 114 offers additional functionality such as it can be hooked to the side walls 108 using mechanisms like hooks and loops or straps. This allows the user to conveniently keep the flap 114 open when desired. This could be helpful for maintaining ventilation or simply allowing easier access to the door or window.

[0046] In one embodiment herein, the tent incorporates plurality of windows 116 positioned on the side walls 108 of the multi-layer insulated tent 100. The windows 116 include fixed windows that offer clear visibility for the users to enjoy the scenery while remaining protected from the elements. The windows 116 also include openable windows that provide the ability to control air circulation within the multi-layer insulated tent 100. By opening and closing them, users can regulate the amount of fresh air entering the multi-layer insulated tent 100, thereby creating a comfortable and well-ventilated environment. All the windows 116 are equipped with the mosquito meshes. These meshes act as barriers for effectively stopping mosquitoes, bugs, and other insects from entering the multi-layer insulated tent 100, thereby ensuring a peaceful and pest-free sleep. Theses meshes are designed to be clear, allowing the users to enjoy the view while still providing insect protection.

[0047] In addition to the standard windows, the multi-layer insulated tent 100 also incorporates ventilation windows positioned above the swing-type door 112 for allowing warm air to escape. Warm air naturally rises, and this window placement facilitates air circulation, thereby promoting a more comfortable temperature within the multi-layer insulated tent 100. These ventilation windows are also strategically placed in the ridge area of the tent. This high position allows for effective air exchange. Stale air and moisture can escape through these windows, thereby preventing condensation buildup on the side walls 108 and creating a fresh and healthy environment for the users. In one embodiment herein, the multi-layer insulated tent 100 comprises a chimney 119 configured to ensure safe evacuation of harmful fumes from the multi-layer insulated tent 100. Incomplete combustion within the three-in-one heating system 118 can lead to carbon monoxide production.

[0048] According to an exemplary embodiment of the invention, FIG. 3 refers to a perspective top view of the multi-layer insulated tent 100 with the three-in-one heating system 118. In one embodiment herein, the three-in-one heating system 118 is a multi-functional system that offers a significant advantage over traditional tents, thereby eliminating the need for separate heating and cooking equipment. The three-in-one heating system 118 is capable of heating the tent space, cooking food, and providing hot water. The primary function is to heat the tent interior. This ensures warmth and comfort for the users even in frigid temperatures. This heating capability is crucial for maintaining a safe and enjoyable experience in harsh arctic environments. The three-in-one heating system 118 also provides a convenient surface for cooking food. This eliminates the need for separate camp stoves, reducing the amount of gear users need to carry. With this feature, the users can prepare hot meals within the multi-layer insulated tent 100, thereby enhancing their comfort and well-being during their expedition.

[0049] According to an exemplary embodiment of the invention, FIG. 4 refers to a block diagram of the three-in-one heating system 118. In one embodiment herein, the three-in-one heating system 118 can provide hot water using a heater 120 that can be used for various purposes, such as preparing drinks, warming up personal hygiene items, or even washing dishes. Having access to hot water can add a significant level of comfort and convenience for users in a remote setting. The three-in-one heating system 118 utilizes a burner 122 fueled by a fuel tank 124. The specific type of fuel used, for example, propane, kerosene, white gas, depends on the specific design and efficiency considerations. The three-in-one heating system 118 comprises a regulator 122 for controlling the oxygen flow to the burner 122. By regulating the oxygen supply, the three-in-one heating system 118 ensures a controlled oxygen flow allows the fuel to burn efficiently, thereby maximizing heat output and minimizing fuel consumption. Regulating oxygen prevents excessive fuel intake, minimizing the risk of overheating or flame blowout.

[0050] The three-in-one heating system 118 incorporates an air blower 128 for ensuring a comfortable and efficient heating experience within the multi-layer insulated tent 100. The air blower 128 efficiently circulates warm air throughout the multi-layer insulated tent 100. Without the air blower 128, warm air naturally rises and collects near the ceiling, leaving the lower areas colder. The air blower 128 promotes even heat distribution, thereby creating a more comfortable and consistent temperature throughout the multi-layer insulated tent 100 for the users. Warm air circulation also helps prevent moisture buildup and condensation on the side walls 108. Condensation can lead to discomfort and potentially mold growth if left unchecked. By promoting air circulation, the air blower 128 maintains a healthy and comfortable living environment.

[0051] The three-in-one heating system 118 also includes a controller 130 for managing various functionalities to ensure optimal performance, safety, and user convenience. The controller 130 allows users to set a desired temperature for the tent interior. The controller 130 may also use a sensor to monitor the current temperature and activates the three-in-one heating system 118 when needed to reach the set point. The controller 130 might manage the power supply to the three-in-one heating system 118. This could involve turning the three-in-one heating system 118 on or off based on user needs.

[0052] The controller 130 might incorporate safety features like overheating protection. If the temperature within the three-in-one heating system 118 exceeds a safe limit, the controller 130 could shut down the heater 120 to prevent damage or fire hazards. The controller 130 may also provide a user interface for setting temperatures, thereby monitoring system status, and potentially controlling other functions like hot water or a light. This interface could be a simple dial, buttons, or even a digital display depending on the design complexity.

[0053] In one embodiment herein, the three-in-one heating system 118 is powered by a power source 132, which can be a rechargeable battery. By incorporating the air blower 128 and the controller 130, the three-in-one heating system 118 offers a more sophisticated and user-friendly heating experience. The air blower 128 ensures even heat distribution and reduces condensation, while the controller 130 provides precise temperature control, safety features, and user convenience. This combination of features contributes to the overall effectiveness and practicality of the three-in-one heating system 118 for tent applications.

[0054] According to another exemplary embodiment of the invention, FIG. 5 refers to an isometric front view of a multi-layer insulated tent 200 for accommodating more users. The tent 200 is a larger version of the multi-layer insulated tent 100. This tent 200 is designed to accommodate more users compared to the previously described multi-layer insulated tent 100. The most straightforward approach would be to increase the floor area of multi-layer insulated tent 200. This could be achieved by extending the length, width, or both dimensions of the tent base compared to multi-layer insulated tent 100. The specific dimensions would depend on the desired number of the users comfortably accommodated in the multi-layer insulated tent 200. In one embodiment herein, the ceiling height of the multi-layer insulated tent 200 could be increased. This would provide a more spacious feeling within the multi-layer insulated multi-layer insulated tent 200 and allow for additional vertical space for storing gear or using bunk beds for sleeping arrangements.

[0055] A more complex design could involve a double-layered tent concept. The multi-layer insulated tent 200 might incorporate an inner tent with a smaller footprint that attaches to the main tent structure. This inner tent could provide additional sleeping space for a few users, while the main tent area offers living space and potentially gear storage. The multi-layer insulated tent 200 could utilize a modular design. This design would allow the users to connect multiple multi-layer insulated tents 100 together using compatible attachment points. This modularity would offer flexibility in creating a larger shelter space by combining individual tents as needed for the number of the users.

[0056] Numerous advantages of the present disclosure may be apparent from the discussion above. In accordance with the present disclosure, is disclosed. The proposed invention provides the multi-layer insulated tent 100 that offers superior thermal insulation capabilities for effective heat retention in extreme cold weather conditions. The multi-layer insulated tent 100 integrates a three-in-one heating system within the tent structure, which provides a safe and reliable source of heat for the users. The multi-layer insulated tent 100 provides proper ventilation and adequate fresh air circulation to create a comfortable and healthy living environment for users. The multi-layer insulated tent 100 integrates a convection-cum-conduction three-in-one heating system for providing space heating, cooking, and boiling hot water with suitable capacity.

[0057] The multi-layer insulated tent 100 provides internal, external, and intermediate fabric layers made out of polyester, waterproof, tear-free material to resist the formation of fungus or algae, a mosquito mesh having a zip to allow air ventilation, and a polymer insulation material that is able to withstand the harsh weather conditions of sub-zero temperatures. The multi-layer insulated tent 100 is made with robust construction techniques and high-quality waterproof and tear-resistant materials to improve the durability and weather resistance of the tent. The multi-layer insulated tent 100 offers a safe, comfortable, and reliable shelter for users engaged in exploration, mountaineering, or other activities in extreme cold weather environments.

[0058] It will readily be apparent that numerous modifications and alterations can be made to the processes described in the foregoing examples without departing from the principles underlying the invention, and all such modifications and alterations are intended to be embraced by this application.

5. CLAIMS:
We Claim:
1. A multi-layered insulation tent (100) with an integrated three-in-one heating system, comprising:
a frame unit (102) comprises plurality of flexible tubes (104), wherein said frame unit (102) is configured to support a tent fabric (106) that defines an interior space to provide accommodation for one or more users,
wherein
said plurality of flexible tubes (104) is configured to detachably connect to each other, respectively, for forming said frame unit (102) with plurality of side walls (108),
said tent fabric (106) comprises one or more layers include an external fabric, an internal fabric and intermediate fabric layers featuring with a TPU lamination and a polymer insulation;
a tent floor (110) configured to detachably connect to the plurality of side walls (108) of the frame unit (102) for preventing air ingress from a bottom portion of said tent floor (110), thereby providing the multi-layer insulated tent (100);
a swing-type door (112) positioned on at least one side wall of the plurality of side walls (108), wherein the swing-type door (112) is equipped with a zipper and a mosquito mesh for ventilation, wherein said mosquito mesh is adapted to prevent mosquitos from entering into said multi-layer insulated tent (100);
a flap (114) positioned on an outer side of the multi-layer insulated tent (100), wherein the flap (114) is configured to cover the zipper from direct exposure to the outside atmosphere;
plurality of windows (116) incorporated on the frame unit (102), wherein the plurality of windows (116) is provided with the mosquito mesh and provides clear visibility for users; and
a three-in-one heating system (118) positioned within said interior space, wherein the three-in-one heating system (118) is configured to heat said interior space, cook food, and provide hot water through a heater (120) using a burner (122),
wherein said three-in-one heating system (118) utilizes both convection and conduction heating techniques to warm up the interior space.
2. The multi-layer insulated tent (100) with the integrated three-in-one heating system as claimed in claim 1, wherein said polymer insulation of the tent fabric (106) is configured to effectively retain heat inside the multi-layer insulated tent (100) for a considerable period of time.
3. The multi-layer insulated tent (100) with the integrated three-in-one heating system as claimed in claim 1, wherein said tent fabric (106) is made of a polyester material that is waterproof, tear-free, and resistant to the formation of fungus or algae, withstand harsh weather conditions, including sub-zero temperatures.
4. The multi-layer insulated tent (100) as claimed in claim 1, wherein the frame unit (102) is lightweight, high-strength, high-tensile aluminum alloy tubular sections and provides modular, collapsible, and inter-lockable facilities.
5. The multi-layer insulated tent (100) as claimed in claim 1, wherein the three-in-one heating system (118) comprises a fuel tank (124) configured to store fuel that burns to generate heat by said burner (122).
6. The multi-layer insulated tent (100) as claimed in claim 1, wherein the three-in-one heating system (118) comprises a regulator (126) configured to control the flow of oxygen to the burner (122).
7. The multi-layer insulated tent (100) as claimed in claim 1, wherein the three-in-one heating system (118) comprises an air blower (128) configured to circulate warm air throughout the multi-layer insulated tent (100).
8. The multi-layer insulated tent (100) as claimed in claim 1, wherein the three-in-one heating system (118) comprises a controller (130) for managing one or more operations of the three-in-one heating system (118) to ensure optimal performance, safety, and user convenience.
9. The multi-layer insulated tent (100) as claimed in claim 1, wherein the three-in-one heating system (118) comprises a power source (132) configured to supply power to operate the three-in-one heating system (118).
10. The multi-layer insulated tent (100) as claimed in claim 1, wherein the flap (114) comprises locking unit configured for opening and closing the plurality of side walls (108) from inside the multi-layer insulated tent (100).
6. DATE AND SIGNATURE:
Dated this 14th May 2024


7. ABSTRACT:
Title: A Multi-layer Insulated Tent with an Integrated Three-In-One Heating System
The present disclosure proposes a high-altitude and multi-layer insulated tent (100) with an integrated three-in-one heating system (118) that offers superior thermal insulation capabilities for effective heat retention in extreme cold weather conditions. The multi-layer insulated tent (100) comprises a frame unit (102), plurality of flexible tubes (104), a tent fabric (106), plurality of side walls (108), a tent floor (110), a swing-type door (112), a flap (114), plurality of windows (116), and the three-in-one heating system (118). The multi-layer insulated tent (100) is specifically designed to withstand harsh weather conditions encountered in high altitude and arctic environments. The multi-layer insulated tent (100) improves ventilation strategies to address condensation issues and provides adequate fresh air circulation for a comfortable and healthy living environment for users in harsh arctic or high-altitude conditions.

, Claims:1. A multi-layered insulation tent (100) with an integrated three-in-one heating system, comprising:
a frame unit (102) comprises plurality of flexible tubes (104), wherein said frame unit (102) is configured to support a tent fabric (106) that defines an interior space to provide accommodation for one or more users,
wherein
said plurality of flexible tubes (104) is configured to detachably connect to each other, respectively, for forming said frame unit (102) with plurality of side walls (108),
said tent fabric (106) comprises one or more layers include an external fabric, an internal fabric and intermediate fabric layers featuring with a TPU lamination and a polymer insulation;
a tent floor (110) configured to detachably connect to the plurality of side walls (108) of the frame unit (102) for preventing air ingress from a bottom portion of said tent floor (110), thereby providing the multi-layer insulated tent (100);
a swing-type door (112) positioned on at least one side wall of the plurality of side walls (108), wherein the swing-type door (112) is equipped with a zipper and a mosquito mesh for ventilation, wherein said mosquito mesh is adapted to prevent mosquitos from entering into said multi-layer insulated tent (100);
a flap (114) positioned on an outer side of the multi-layer insulated tent (100), wherein the flap (114) is configured to cover the zipper from direct exposure to the outside atmosphere;
plurality of windows (116) incorporated on the frame unit (102), wherein the plurality of windows (116) is provided with the mosquito mesh and provides clear visibility for users; and
a three-in-one heating system (118) positioned within said interior space, wherein the three-in-one heating system (118) is configured to heat said interior space, cook food, and provide hot water through a heater (120) using a burner (122),
wherein said three-in-one heating system (118) utilizes both convection and conduction heating techniques to warm up the interior space.
2. The multi-layer insulated tent (100) with the integrated three-in-one heating system as claimed in claim 1, wherein said polymer insulation of the tent fabric (106) is configured to effectively retain heat inside the multi-layer insulated tent (100) for a considerable period of time.
3. The multi-layer insulated tent (100) with the integrated three-in-one heating system as claimed in claim 1, wherein said tent fabric (106) is made of a polyester material that is waterproof, tear-free, and resistant to the formation of fungus or algae, withstand harsh weather conditions, including sub-zero temperatures.
4. The multi-layer insulated tent (100) as claimed in claim 1, wherein the frame unit (102) is lightweight, high-strength, high-tensile aluminum alloy tubular sections and provides modular, collapsible, and inter-lockable facilities.
5. The multi-layer insulated tent (100) as claimed in claim 1, wherein the three-in-one heating system (118) comprises a fuel tank (124) configured to store fuel that burns to generate heat by said burner (122).
6. The multi-layer insulated tent (100) as claimed in claim 1, wherein the three-in-one heating system (118) comprises a regulator (126) configured to control the flow of oxygen to the burner (122).
7. The multi-layer insulated tent (100) as claimed in claim 1, wherein the three-in-one heating system (118) comprises an air blower (128) configured to circulate warm air throughout the multi-layer insulated tent (100).
8. The multi-layer insulated tent (100) as claimed in claim 1, wherein the three-in-one heating system (118) comprises a controller (130) for managing one or more operations of the three-in-one heating system (118) to ensure optimal performance, safety, and user convenience.
9. The multi-layer insulated tent (100) as claimed in claim 1, wherein the three-in-one heating system (118) comprises a power source (132) configured to supply power to operate the three-in-one heating system (118).
10. The multi-layer insulated tent (100) as claimed in claim 1, wherein the flap (114) comprises locking unit configured for opening and closing the plurality of side walls (108) from inside the multi-layer insulated tent (100).