1. The Field of the Invention
The present invention generally relates to heating devices. More particularly, the present invention relates to a portable air heating system for use in remote areas, during emergency circumstances, with constructed shelters and/or where large quantities of heated air are desired.
2. The Relevant Technology
The popularity of outdoor recreation in the United States has grown tremendously in recent years. An ever increasing number of outdoor activities have become more accessible to a greater number of people, resulting in a greater proportion of the general population spending more time in less developed and remote areas of the country. Examples of such recreational activities include hiking, biking, camping, hunting, rock climbing, and mountain climbing.
This increased interest and participation in outdoor recreation has increased the demand for products that provide some of the comforts of modern living. For instance, portable tents of many shapes and sizes have been manufactured to provide privacy and shelter during camping and overnight excursions to remote outdoor areas. Additionally, products such as folding chairs, compact cooking apparatus, backpacks, and portable food storage devices, such as coolers, enable persons to enjoy activities in remote areas while still enjoying some of the necessities or comforts of modern life.
These modern comforts are useful for other individuals that work in adverse weather conditions. Many occupations require people and animals to work in adverse weather conditions to protect the lives of people, clean-up hazardous materials, or complete construction projects on time. As with recreational activities, portable tents of many shapes and sizes have been manufactured to provide privacy and shelter for these workers.
A common concern for persons spending time in the outdoors relates to keeping warm. Without the benefit of temperature-regulated buildings or structures, a person in a remote area or otherwise exposed to the elements is often subject to extreme temperature variations. For example, mountainous areas are a popular destination for campers, hikers, bikers, climbers, and hunters. Yet, because of their high elevation, these areas often experience much lower temperatures than are comfortable, especially at night. In the event that campers, hikers, bikers, climbers, and hunters become injured or lost, rescue personnel must combat the extreme temperatures to extricate the recreational enthusiast. Similarly, police officers, medical personnel, fire service personnel, hazardous material clean-up crews, and military personnel continue working during all weather conditions.
Portable heat sources are often used to help protect oneself from the low temperatures frequently encountered while in the outdoors, whether during recreation or occupational activities. One example of such a portable heat source is a small packet containing substances that, when activated by pressure, produce an exothermic chemical reaction, thereby providing heat for a limited amount of time. Once activated, the packet can be placed close to the body part desired to be warmed, such as the hands, feet, or face, thereby providing relief from the cold. Despite their convenience, such heat packets are of limited value because of their small size and limited output of heat. Also, these packets cannot heat an enclosed space, such as the interior of a structure like a tent, tent trailer, camper, or camp trailer.
Portable direct air combustion heaters have also been utilized for purposes of providing heat in the outdoors where other sources of heat, such as electricity, are unavailable. These combustion heaters burn a fuel, such as gasoline or propane, to produce relatively large quantities of heat. These direct air combustion heaters are commonly used in the outdoors to heat enclosed areas, such as the interior of a tent, tent trailer, camper, or camp trailer. Notwithstanding their ability to heat an enclosed interior space, direct air combustion heaters can pose serious safety hazards. In particular, these heaters burn a mixture of fuel and air in a combustion reaction to produce heat. This reaction also creates a byproduct of potentially dangerous gases, such as carbon monoxide and carbon dioxide. These exhaust gases are potentially very dangerous and in some cases deadly because they may replace the oxygen within an enclosed environment, such as a tent, tent trailer, camper, or camp trailer, and potentially asphyxiate or at least make the persons therein ill. Much care, therefore, must be taken with such heaters to provide proper ventilation to avoid illness and/or asphyxiation by the exhaust gases. Additionally, placing direct air combustion heaters inside the tent or camp trailer poses a fire hazard due to the flammable materials often stored inside such structures, or from which such structures are manufactured.
In light of the above-described problems associated with conventional portable heaters, a need exists for a reliable and highly portable heat producing system that efficiently and safely provides relatively large quantities of heated air to persons and structures in remote areas. Moreover, a need exists for a portable heater that is easy to assemble and disassemble, and can produce heat safely without creating elevated levels of potentially dangerous and even deadly exhaust gases, including carbon monoxide, within an enclosed space, such as a tent, tent trailer, camper, camp trailer, shelters, or other structure to be heated.
In accordance with the general principles of the present invention, as embodied and broadly described herein, the foregoing needs can be met by a portable air heating system. The portable air heating system can be also compact and portable, thereby allowing it to be easily transported. Due to its simple design, the system can be also easily set up for use in a minimum amount of time. The portable air heating system can be particularly useful in remote areas where access to more conventional methods for providing heat are unavailable, though the heating system may also be utilized in a variety of other locations as well. The air heated by the heating system can be isolated from combustion-produced exhaust gases, allowing the air within an enclosed space, such as a tent, to be heated safely.
One portion of a portable air heating system can be an air transfer assembly that both draws air into the system and expels air out of the system. The air transfer assembly can include an air intake conduit and air outlet conduit, both of which have one end connected to a heat transfer housing. A motorized fan disposed within the air intake conduit can draw air into the air intake conduit through the free end, and expel the air through passages defined in the heat transfer housing and through the air outlet conduit. The motorized fan can be powered by an electrical source, such as a battery. The air transfer system can allow the user to draw air from either inside or outside of the location desired to be heated. For example, the air transfer assembly may be used to bring fresh outside air into a tent, or it may be used to re-circulate and/or reheat the air already inside the tent. The air transfer assembly can also be used to direct the heated air into the tent or other structure.
In one exemplary portable air heating system, the system can include a heat transfer housing which can include one or more exterior walls defining the perimeter of the housing, and a plurality of passages or heat transfer tubes extending from one side of the housing to the other side of the housing. The heat transfer tubes, which transport the air to be heated through the heat transfer housing, can isolate the air to be heated from the harmful exhaust gases produced by burning fuel during operation of the air heating system. Additionally, the heat transfer tubes may be constructed of copper or other conductive material, and can be arranged in a pattern that maximizes their exposure to heat produced by a burner during operation of the air heating system. Thus, the heat transfer tubes can be configured to absorb the heat produced by the burner and transfer it to the air flowing through the heat transfer tubes. The heat transfer housing can include one or more heat deflectors that assist in directing the heat produced by the burner toward the heat transfer tubes. The heat deflectors can also increase the safety of the system by reflecting the heat away from the exterior walls of the heat transfer housing so that the walls are not the primary point of heat contact.
The portable air heating system can also include a fuel burner assembly. The fuel burner assembly can include one or more fuel burners, located directly below the heat transfer tubes and at least partially within the exterior walls of the heat transfer housing, a fuel supply tube connected to the burner(s), and a connector for connecting the fuel supply tube to a fuel source, such as one or more liquid propane tanks. The connector can also include a valve for controlling the flow of fuel to the one or more burners.
To operate one exemplary portable air heating system, the system can be first securely placed on the ground or other stable location outside the structure to be heated, such as a tent. In one configuration, this can include moving a support structure upon which is mounted the heat transfer assembly, the fuel burner assembly, and optionally the fuel source to a location near the tent. Following placing the support structure, the free end of the air intake conduit can be placed outside the structure to be heated, where it has access to fresh, ambient air. Alternatively, the free end of the air intake conduit may be positioned inside the structure to be heated to re-circulate air from inside the structure through the heat transfer housing circulate. Re-circulating the air inside the structure allows the structure to be heated more quickly and to a higher temperature. The free end of the air outlet conduit can be disposed within the structure to supply heated air to the structure.
Next, the fuel supplied to the burner(s) through the fuel supply tube can be ignited to produce an exothermic combustive reaction within the heat transfer housing. Turning on the motorized fan produces a flow of air through the air intake conduit, the heat transfer tubes, and the air outlet conduit. The burning fuel heats the heat transfer tubes, which are thermally conductive so as to absorb a significant portion of the heat produced by the burner. This heat warms the air passing through the heat transfer tubes. The heated air then can be directed through the outlet conduit to exit the system and enter the structure to be heated. In this way, the interior of a tent, a portable structure, a fixed structure, a vehicle, or any other structure to which heated air can be directed or re-circulated can be heated.
The air flowing through the air transfer assembly does not mix with the exhaust gases. That is, the heated air at no point comes into contact with the potentially dangerous gases, such as carbon monoxide, produced as a byproduct of the fuel combustion. These exhaust gases, which are produced in the heat transfer housing located exterior to the structure, pass harmlessly out of the heat transfer housing and into the atmosphere during operation of the heating system. Thus, the tent or other structure can be safely isolated from the harmful exhaust gases during safe heating of the interior of the structure. This results in a comfortable and safe environment for persons within the tent or other structure.
The portable heating system may also be employed as a body warmer by directing the flow of heated air exiting the air outlet conduit over one's body. In an alternate configuration, a portion of the heat transfer housing may be used as a heating surface for warming food or even warming or drying clothing. In still another configuration, the flow of heated air exiting air heating system can warm equipment, chemicals, temperature sensitive instruments, or other devices so that they remain within a desired temperature range.
These and other objects and features of the present invention will become more fully apparent from the following description and appended claims, or may be learned by the practice of the invention as set forth hereinafter.
To further clarify the above and other advantages and features of the present invention, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. It is appreciated that these drawings depict only typical embodiments of the invention and are therefore not to be considered limiting of its scope. The invention will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:
Reference will now be made to the figures where various structures will be provided with reference number designations. It is understood that the drawings are diagrammatic and schematic representations of possible embodiments of the invention, and are not intended to limit the scope of the present invention nor are they necessarily drawn to scale. Further, one skilled in the art will appreciate that terms such as top, bottom, upper, and lower as used herein are merely words used to describe the accompanying figures, and are not meant to limit the scope of the present invention in any way.
As can be seen from
With continued reference to
In the depicted arrangement of
Returning to
As depicted in
As can be seen in
In one possible embodiment, illustrated in
In another embodiment, electrical cable leads 26D may be electrically connected to a 12 volt cigarette plug configured to cooperate with a car, boat, camper and the like. Alternatively, electrical cable leads 26D may be attached to a rechargeable battery or other suitable power source disposed near heating system 10 for added convenience and portability. Motorized fan 26, in one configuration, can be structurally supported by and housed in a sleeve 28 comprising thermoplastic or similar material that, in turn, can be fixedly disposed within air intake conduit 22 near first end 22A thereof by conventional fastening devices (not shown), such as a coupler. It will be appreciated that although sleeve 28 depicted in
It will also be appreciated that while motorized fan 26 is depicted as disposed within air intake conduit 22, motorized fan 26 could instead be attached to first end 22A of air intake conduit 22 or attached to an exterior of air intake conduit 22. Various other arrangements are capable of carrying out the intended function thereof. One skilled in the art will appreciate that motorized fan 26 may be disposed in other locations in portable air heating system 10 while still preserving its functionality. Likewise, motorized fan 26 may differ in size and configuration from that explicitly described herein. For example, a fan powered by solar energy could be disposed in air outlet conduit 24 in order to direct air through air heating system 10.
As depicted in
More specifically, returning to
Reference now is made to
Heat transfer housing 18 can include a first end portion 102, a middle portion 104, and a second end portion 106. First end portion 102 may be integral with middle portion 104 or fixedly attached to middle portion 104 using any one of several attachment or fastening methods well known in the art, such as welding or mechanical fasteners. First end portion 102 includes a substantially planar top surface 102A and sides 102B. Top surface 102A, when heated by burner 52 during the operation of portable air heating system 10, may serve as a heating surface for warming things such as food, drinks, articles of clothing, etc. Sides 102B of first end portion 102 each include a plurality of openings 102C for venting exhaust gases from heat transfer housing 18. In one embodiment, sides 102B of first end portion 102 have approximately 14 openings 102C formed therein for venting combustion gases from heat transfer housing 100. It will be appreciated that various other numbers of openings could be formed in sides 102B of first end portion 102 to perform the function thereof. In addition, it will also be appreciated by one skilled in the art that openings 102C formed in sides 102B could have various other configurations other than round. Openings 102C could be square, rectangular, triangular, elliptical, octagonal, oval, polygonal, or numerous other shapes or combinations thereof and still perform the function thereof. It will also be appreciated that openings 102C could also be formed in top surface 102A of first end portion 102.
In one possible embodiment, depicted in
Second end portion 106 of heat transfer housing 18 may also be integral to middle portion 104 or may be fixedly attached to middle portion 104 using any one of several attachment or fastening methods well known in the art, such as welding or mechanical fasteners. As depicted in
In one embodiment depicted in
It will be appreciated that various other numbers of apertures 106C could be formed in segments 106B of second end portion 106 to perform the function thereof. In addition, it will also be appreciated by one skilled in the art that apertures 106C formed in segments 106B could have various other configurations than merely being round. These apertures 106C could be square, rectangular, triangular, elliptical, octagonal, oval, polygonal, or numerous other shapes or combinations thereof and still perform the function thereof.
Returning to
As illustrated in
Referring to
Returning to
Turning again to
In one embodiment, openings 116 are arranged on side 108C and, consequently, side 108D (not shown) of housing portion 108 with some of openings 116 being in an arc-like or curved configuration indicated by line 116A. Other openings 116 are positioned around those openings 116. In one embodiment depicted in
Referring now to
As illustrated, heat transfer tubes 120 extend between each of the pairs of opposing openings 116. Each heat transfer tube 120 absorbs heat emitted by burner 52 during combustion of the fuel, transferring the heat to air flowing through heat transfer tubes 120. In one embodiment, heat transfer tubes 120 are composed of copper, metals, or other conductive material and are configured to connect opposing holes 116 in the side walls 108C and 108D of housing portion 108. It will be appreciated that heat transfer tubes 120 could be composed of other materials that are capable of absorbing the heat emitted by burner 52 and transferring the same to the air flowing through heat transfer tube 120.
In one embodiment, each heat transfer tube 120 is sufficiently long to allow each heat transfer tube 120 to extend from one opening 116 on right side 108C of housing portion 108 to the opposing opening 116 on left side 108D of housing portion 108. In one embodiment, the distance between opposing sides 108C and 108D is approximately 5.2 inches. It will be appreciated that various other lengths of heat transfer tubes 120 may be used as long as each heat transfer tube 120 is configured to cooperate with opposing openings 116, and isolates the air being heated from the harmful exhaust gases. It will be appreciated that although heat transfer tube 120 is illustrated as being a hollow round member, heat transfer tube 120 could have various other shapes or configurations as long as it is hollow. By way of example and not limitation, heat transfer tube 120 could be oval, elliptical, square, rectangular, polygonal, or the like and any combination thereof as long as it is a hollow member.
Another possible embodiment of an isolating means for isolating the air being heated from the exhaust gas is a single tubular member providing a fluid connection from air intake conduit 22 through heat transfer housing 18 to air outlet conduit 24. By way of example and not limitation sleeves 112 and 114 could be one tubular member extending through heat transfer housing 18. Another possible embodiment of such an isolating means includes one or more tubes providing a fluid connection from air intake conduit 22 through heat transfer housing 18 to air outlet conduit 24, wherein the tubes comprise multiple vertical or horizontal dividers to maximize the length of the pathway through heat transfer housing 18, and to maximize the surface area of the tubes in contact with the air flowing there through.
In one embodiment illustrated in
As illustrated in
As shown in
In addition to directing the heat toward heat transfer tubes 120, heat deflectors 126 also serve as a heat insulator that prevents at least a portion of the heat produced by burner 52 from reaching front and rear sides 108A and 108B of housing portion 108, respectively, thereby keeping the surface of housing portion 108 cooler during operation of air heating system 10 than would be possible without heat deflectors 126. Heat deflectors 126 thereby increase the safety of the air heating system 10 device by reflecting the heat produced by burner 52 away from housing portion 108 so that housing portion 108 is not the primary point of heat contact.
Turning now to
The following discussion relates to operation of air heating system 10. It will be appreciated that while the discussion is referencing
As seen from
To initiate a flow of heated air to a desired location, a user initially turns on motorized fan 26 by electrically connecting electrical cable leads 26D to an appropriate power source, for example, to a 12-volt car battery 130 via clamps 26E as illustrated in
Once motorized fan 26 is turned on, the user ignites the fuel at burner 52 by opening fuel valve 62 (
Heat transfer tubes 120, comprising a thermally conductive material such as by way of example and not limitation, copper or stainless steel, readily absorb the radiated heat and transmit the heat to the air flowing there through. The heated air continuously flows into tent 12 via air outlet conduit 24, thereby heating the interior of tent 12. If portable air heating system 10 is used according to the configuration shown in
Alternatively, first end 22A of intake conduit 22 may be disposed exterior to tent 12 as illustrated in
After transmitting a significant portion of its heat to heat transfer tubes 120, the remaining heat and exhaust gases produced by burner 52 continue to rise past heat transfer tubes 120 to top surface 102A. This remaining heat and exhaust gases heat top surface 102A, and then safely exit into the atmosphere via openings 102C in top surface 102A or via the vent openings 102C disposed on sides 102B of first end portion 102. Heated top surface 102A may be used as a heating surface for such things as food or water placed in a container 132. Portable air heating system 10 can be used in adverse weather without the rain or snow from gaining access to the burner because of the configuration of heat transfer housing 100 and particularly surface 102A. Further, because the exhaust gases produced by burner 52 are isolated from air transfer assembly 20 during operation of portable air heating system 10, the heated air flowing through air transfer assembly 20 is free from contamination by the harmful exhaust gases.
In addition to heating an enclosed structure such as a tent, portable air heating system 10 may also be used as a body warmer by directing the flow of heated air from air outlet conduit 24 directly onto a person. It is also understood that burner 52 may be turned off by the user at any time during operation of portable air heating system 10, thereby allowing unheated air to flow through the air transfer assembly 20 and into tent 12.
It is appreciated that the details of various features of portable air heating system 10 could be varied while still preserving the same functionality. For example, in an alternative embodiment of portable air heating system 10, second end portion 106 of heat transfer housing 18 is not fixedly attached to middle portion 104 as shown in
The removability feature of second end portion 106 of heat transfer housing 100 provides expanded utility to portable air heating system 10. For instance, removable second end portion 106 may be separated from air heating system 10 and joined to other components to form a portable stove unit for cooking, or to a portable shower unit to function as a water heater.
Turning now to
Air heating system 200 can be used in a more commercial or industrial settings where large temperature differences exist between the ambient air temperature and the desired air temperature within a temporary or permanent structure and/or the temporary or permanent structure has a large interior volume. Air heating system 200 is also useful where large quantities of warm air are needed, such as, in military, disaster or hazardous waste clean-up, fire, hospital, decontamination, and other similar settings.
As illustrated in
Mounted to support frame 202 are wheels 206. These wheels 206 facilitate easy mobility for air heating system 200. Although reference is made to wheels 206, one skilled in the art will understand that alternative embodiments of air heating system 200 can optionally be disposed on skis, sleds, tracks, or other structures that aid in making air heating system 200 mobile. Various alternate configurations would be understood by those skilled in the art in light of the teaching contained herein.
With continued reference to
In one possible configuration, first end 222a of air intake conduit 222 can accommodate a motorized fan 226 that aids in directing air towards heat transfer housing 210. The motorized fan 226 can have similar configurations to and functions as fan 26 (
Motorized fan 226 can be configured to include a power source (not shown). It will be appreciated that various types of power sources could be utilized for motorized fan 226, such as batteries or adaptors to connect motorized fan 226 to a separate power source such as a car battery, generator, or other power source. Although not shown in
In another embodiment, the electrical cable leads may be electrically connected to a twelve volt cigarette plug configured to cooperate with a car, boat, camper and the like. Alternatively, the electrical cable leads may be attached to a rechargeable battery or other suitable power source disposed near heating system 200 for added convenience and portability.
Cooperating with air transfer assembly 220 is heat transfer housing 210. Heat transfer housing 210 functions in a similar manner to heat transfer housing 18 (
As shown in
Similarly, base 216 includes a plurality of openings 232 that provide an inlet path for combustion gases. For instance, as fuel burner assembly 250 creates the heat necessary to heat air passing through heat transfer housing 210, air can be drawn into heat transfer housing through openings 232. In addition to openings 232, base 216 includes a hole 234 that accommodates a portion of fuel burning assembly 250 and one or more holes 236 that can receive one or more fasteners (not shown) to attach heat transfer housing 210 to support frame 202 and/or base 216 to main body 212. Other methods of attachment are known to attach heat transfer housing 210 to support frame 202, such as, but not limited to, welds, other mechanical fasteners, or other structures that allow heat transfer housing 210 to be permanently or releasably connected to support frame 202.
Front panel 218 can mount to main body 202. Front panel 218 has a generally “C” shaped configuration having flanges 240 that mount to main body 212. A number of holes 242 in front panel 218 provide access to portions of fuel burner assembly 250. The front panel 218 aids to separate a user from main body 212 and prevent inadvertent contact with main body 212 during use.
The main body 212 has a front portion, a rear portion, and side portions. The front portion includes two channels 244 that enable a portion of fuel burner assembly 250 to extend there through to cooperate with holes 242 of front panel 218. The size and configuration of channels 244 can vary based upon the particular configuration of fuel burner assembly 250, such as, but not limited to, the number of burners, ignition devices, connectors, valves, etc.
The front portion, rear portion, and side portions of main body 212 define an interior enclosure for burning fuel and transferring heat to the air flowing through air transfer assembly 220. Main body 212 can include an air intake sleeve 246 mounted to one side portion and an air outlet sleeve 248 mounted to the other side portion, in a similar configuration to the embodiment illustrated in
In some cases, a slight deformation of second ends 222b and 224b (
Generally, sleeves 246 and 248 can be hollow members composed of steel, aluminum, metal, or other suitable material. Sleeves 246 and 248 can have various configurations so long as they cooperate with air inlet conduit 222 and air outlet conduit 224 respectively. Consequently, sleeves 246 and 248 can be round, cylindrical, oval, square, rectangular, polygonal, and parabolic, combinations thereof, or other configuration that are complementary to the configuration of air intake conduit 222 and air outlet conduit 224.
As mentioned above, main body 212 provides a structural support for portions of the fuel burner assembly 250. Fuel burner assembly 250, as shown in
The burners 252 can be 35,000 BTU burners and fabricated from cast-iron or other material capable of withstanding the elevated temperatures. Although reference is made to 35,000 BTU burners, one skilled in the art will understand that burners 252 can be rated more or less than 35,000 BTU. Additionally, although only two burners are shown, one can understand that air heating system 200 can include various numbers of burners.
To supply burners 252 with fuel from fuel source 204 (
Cooperating with burners 252 are two optional ignition devices 264. In the exemplary configuration, ignition devices 264 are electric or piezo-electric spark igniters or automatic lighting devices. By manipulating a button 266 of ignition device 264, a spark is created at an electrode 268 that ignites fuel flowing through supply tube 256, connectors 258, and valves 260 to produce the desired heating. It will be understood that rather than having optional ignition devices 264 a user can manually ignite fuel exiting from burners 252.
As shown in
As illustrated in
Each heat transfer tube 270 absorbs heat emitted by burner 252 during combustion of the fuel, transferring the heat to air flowing through heat transfer tubes 270. In one embodiment, heat transfer tubes 270 are composed of copper, metals, or other conductive material. It will be appreciated that heat transfer tubes 270 could be composed of other materials that are capable of absorbing the heat emitted by burner 252 and transferring the same to the air flowing through heat transfer tube 270.
It will be appreciated that various lengths of heat transfer tubes 270 may be used as long as each heat transfer tube 270 is configured to cooperate with heat transfer housing 210, and isolates the air being heated from the harmful exhaust gases. It will be appreciated that although each heat transfer tube 270 is illustrated as being a hollow round member, each heat transfer tube 270 could have various other shapes or configurations as long as it is hollow. By way of example and not limitation, each heat transfer tube 270 could be oval, elliptical, square, rectangular, polygonal, or the like and any combination thereof as long as it is a hollow member.
Although heat transfer tube or member 270, whether alone or in combination with the other portions of heat transfer housing 210, is one example of an isolating means, another possible embodiment of an isolating means for isolating the air being heated from the exhaust gas is a single tubular member (not depicted) providing a fluid connection from air intake sleeve 246 through heat transfer housing 210 to air outlet sleeve 248. By way of example and not limitation, sleeves 246 and 248 could be one tubular member extending through heat transfer housing 210. Yet another possible embodiment of such an isolating means includes one or more tubes providing a fluid connection from air intake conduit 222 through heat transfer housing 210 to air outlet conduit 224, wherein the tubes have multiple vertical or horizontal dividers to maximize the length of the pathway through heat transfer housing 210, and to maximize the surface area of the tubes in contact with the air flowing there through.
To aid with positioning heat transfer tubes 270, each side portion of main body 212 includes a plurality of openings 272, which are shown in
In the illustrated configuration, openings 272 are in an arc-like formation indicated by line 274. Other openings 272 are positioned around this arc-like arrangement to maximize heat transfer from the combustion to the heat transfer tubes 270. In this configuration, heated air passes by one or more of heat transfer tubes 270, thereby heating heat transfer tubes 270 and transferring the generated heat to heat transfer tubes 270. It will be understood that opening 272 can be formed in any configuration and need not be formed in the arc-like arrangement. For instance, openings 272 can be arranged in horizontal columns or vertical rows. Additionally, openings 272 can be arranged in diagonal lines, circular or curved patterns or configurations, or any other configuration that allows heat to be transferred to transfer tubes 270. Various orientations and numbers of openings 272, and consequently heat transfer tubes 270, are possible.
Also disposed within the interior of heat transfer housing 210 are multiple optional heat deflectors 280. As depicted in
By directing the heat generated by burners 252 toward heat transfer tubes 270 and preventing at least a portion of the heat produced by burner 252 from reaching the front, rear, and side portions of main body 212, optional deflectors 280a-280d keep the surface of main body 212 cooler during operation of air heating system 200 than would be possible without the inclusion of heat deflectors 280a-280d. Heat deflectors 280a-280d thereby increase the safety of the air heating system 200 device by reflecting the heat produced by burners 252 away from main body 212 of heat transfer housing 210 so that heat transfer housing 210 is not the primary point of heat contact. It will be understood by one skilled in the art that air heating system 200 can perform the function of heating air without the inclusion of optional heat deflectors 280a-280d.
A first end 282a-282d of each deflector 280a-280d is connected to the inner surfaces of main body 212. Deflectors 280a and 280c are configured to narrow heat transfer housing 210 in a direction from burners 252 toward heat transfer tubes 320, thereby concentrating or directing the heat produced by burners 252 to an area proximate heat transfer tubes 270. In one embodiment, the heat deflectors are composed of spring steel, but it will be appreciated that the heat deflectors could be constructed from various other suitable materials known in the art. With the heat transfer tubes 270 in the arc-like configuration, the heat produced by burners 252 can efficiently transferred to one or more of heat transfer tubes 270. The heated air can be directed to one or more of heat transfer tubes 270, with the highest density of heat transfer tubes 270 being within the middle of the space defined by deflectors 280a-280d. This arc-like arrangement maximizes heat transfer from the combustion to the heat transfer tubes 270.
The operation of air heating system 200 depicted in
When the fan 226 is operating to draw air into the free end of the intake conduit 222a and through the heat transfer tubes 270, the user can open the valves 260 and ignite the burners 252 by turning the control knobs 262 and manually lighting or by manipulating the optional piezo-electric spark igniters of the ignition devices 264. Lighting the fuel begins a sustained combustion at the surface of the burners 252 and creates a large quantity of heat that is transmitted via radiation and convection in a generally upward direction. The heat is concentrated by the heat deflectors 280a-280d toward the heat transfer tubes 270, which are arranged in one embodiment to maximize heat transfer from the combustion to the heat transfer tubes 270.
Heat transfer tubes 270, having a thermally conductive material such as, by way of example and not limitation, copper or stainless steel, readily absorb the radiated heat and transmit the heat to the air flowing there through. The heated air continuously flows into the structure via the air outlet conduit 224, thereby heating the interior of the structure.
After transmitting a significant portion of its heat to the heat transfer tubes 270, the remaining heat and exhaust gases produced by the burners 252 continue to raise past heat the transfer tubes 270 to the top 214 of the heat transfer housing 210. This remaining heat and exhaust gases heat the top 214 of the heat transfer housing 210, and then safely exit into the atmosphere via the openings 230 formed therein. The heated top 214 may be used as a heating surface for such things as food or water placed in a container (not shown). The portable air heating system 200 can be used in adverse weather without the rain or snow from gaining access to the burners 252 because of the configuration of the heat transfer housing 210. Further, because the exhaust gases produced by the burners 252 are isolated from the air transfer assembly 220 during operation of the portable air heating system 200, the heated air flowing through the air transfer assembly 220 is free from contamination by the harmful exhaust gases.
As with the other air heating systems described herein, generally, the air heating system 200 of the present invention can be used to provide heated air that can be directed to a structure, a vehicle, a human or animal body, or other location where heated air is desired. Generally, the air heating system can heat air received externally to a structure and then supply the interior of the structure with this heated air. Alternatively, the air heating system can heat or reheat air within the interior of a structure by drawing the air within the structure through the heat transfer tubes and returning the heated or reheated air back into the interior of the structure. The air heating system 200, therefore, produces a continuous supply of heated air to a structure. Desirably, the air heated by air heating system 200 is free of significant concentrations of harmful and potentially dangerous exhaust gases, and is therefore suitable for use in enclosed structures.
The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
This is a continuation application of U.S. patent application Ser. No. 10/960,427, filed Oct. 6, 2004, entitled “Portable Air Heating System”, which is a continuation-in-part application of U.S. patent application Ser. No. 10/215,918, filed Aug. 9, 2002, entitled “Portable Air Heating System”, which claims priority to and the benefit of U.S. Provisional Patent Application Ser. No. 60/311,647, filed Aug. 10, 2001, entitled “Portable Air Heating System,” and U.S. patent application Ser. No. 10/960,427 also claims priority to and the benefit of U.S. Provisional Patent Application Ser. No. 60/509,226, filed Oct. 6, 2003, entitled “Portable Air Heating System”, the disclosures of which are incorporated herein by this reference.
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6668914 | Langl | Dec 2003 | B2 |
6941677 | Adrian | Sep 2005 | B2 |
Entry |
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U.S. Appl. No. 60/311,647, filed Aug. 10, 2001, Adrian. |
U.S. Appl. No. 60/509,226, filed Oct. 6, 2003, Adrian. |
U.S. Appl. No. 10/960,427, filed Oct. 6, 2004, Adrian. |
U.S. Appl. No. 10/215,918, Oct. 21, 2003, Office Action. |
U.S. Appl. No. 10/215,918, Jul. 13, 2004, Office Action. |
U.S. Appl. No. 10/215,918, Apr. 6, 2005, Notice of Allowance. |
U.S. Appl. No. 10/960,427, Jan. 10, 2007, Office Action. |
U.S. Appl. No. 10/960,427, Oct. 4, 2007, Office Action. |
U.S. Appl. No. 10/960,427, May 1, 2008, Office Action. |
U.S. Appl. No. 10/960,427, Jun. 10, 2009, Office Action. |
U.S. Appl. No. 10/960,427, Dec. 28, 2009, Office Action. |
U.S. Appl. No. 10/960,427, Oct. 1, 2010, Office Action. |
U.S. Appl. No. 10/960,427, Apr. 8, 2011, Notice of Allowance. |
Number | Date | Country | |
---|---|---|---|
60311647 | Aug 2001 | US | |
60509226 | Oct 2003 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 10960427 | Oct 2004 | US |
Child | 13210254 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 10215918 | Aug 2002 | US |
Child | 10960427 | US |