Liquid fuel stove apparatus

Information

  • Patent Grant
  • 6450801
  • Patent Number
    6,450,801
  • Date Filed
    Friday, October 29, 1999
    25 years ago
  • Date Issued
    Tuesday, September 17, 2002
    22 years ago
Abstract
A stove apparatus includes a frame having an interior opening. A burner is mounted within the opening. A liquid fuel container is mounted on the frame within the opening. A fuel conduit extends between the container and the burner. A heat shield extends about the burner and separates the burner from the fuel container. Preferably the apparatus has a manually operable device which simultaneously regulates a valve controlling a flow of fuel from the fuel container to the burner and a control device controlling the output of a compressor supplying compressed air to the burner. The compressor may have a suction port. The apparatus then includes a suction conduit connecting the suction port to the fuel container, whereby the compressor can selectively draw fuel into the container. The fuel container may have a vent body mounted thereon. The suction conduit is connected to the vent body. The body has a valve for preventing fuel from entering the conduit from the container. The valve may include a chamber with a valve seat at the top of the chamber. A check valve ball, buoyant in the fuel, is movably mounted in the chamber. If fuel is drawn into the chamber, the check valve ball floats to the top of the chamber and blocks the fuel from entering the suction conduit.
Description




BACKGROUND OF THE INVENTION




This invention relates to liquid fuel stoves and, in particular, to portable liquid fuel stoves for military use.




Portable stoves are used for a variety of purposes such as military operations. They are used in range ovens, steam tables, tray ration heaters, field sanitation equipment and stock pot heating racks. These appliances perform such functions as roasting, grilling, broiling, frying, heating water and other liquids and baking. They are typically utilized in such field equipment as tents, other shelters, containerized mobile kitchens and mobile kitchen trailers. These appliances may also be used in an open field without the benefit of shelter.




Such stoves may operate under difficult field conditions and must be reliable in operation and perform to a high level in order to meet the demands of some users.




Some previous portable stoves have had serious problems and disadvantages. They sometimes take a long time to ignite, are not reliable and may perform inadequately if not operated according to strict procedures. Some are not capable of being re-fueled in an appliance, making it necessary to remove the stoves in order to fuel them. This is both labor intensive and inconvenient in the relatively tight quarters of field kitchens for example. Moreover, some are also labor intensive to operate and maintain. They utilize a pressurized fuel tank which contains an explosive fuel. This may present a potential hazard.




Currently there is a demand for a replacement for certain types of portable stoves. The replacement units preferably should be robust in terms of durability. Service and maintenance should be simple, as they often must be conducted by a technically untrained stove operator. Field service should not require specialized tools. Cleaning should be accomplished by simple procedures such as wiping the stoves down with a soapy wet cloth. Such stoves must be rugged enough to withstand transportation as unrestrained cargo in ground vehicles, often moving over rough terrain.




Also, such units should be capable of burning certain fuels, such as military JP-8 fuel, which some previous stoves are incapable of burning. Also, for some applications, a multifuel stove is desired which would be capable of burning such alternative fuels as JP-8; DFA, DF-1 and DF-2 (military diesel fuels), #1 and #2 diesel fuel, kerosene and JP-5.




Accordingly, it is an object of the invention to provide an improved stove adaptable for a wide variety of purposes including installation in existing appliances such as range ovens, steam tables, tray ration heaters, field sanitation equipment and stock pot heating racks.




It is also an object of the invention to provide an improved stove which is capable of performing such functions as roasting, grilling, broiling, frying, heating water and other liquids and baking.




It is also an object of the invention to provide an improved stove which is capable of being utilized in such field equipment as tents, other shelters, containerized mobile kitchens and mobile kitchen trailers.




Is a further object of the invention to provide an improved stove which is capable of burning JP-8 fuel.




It is a still further object of the invention to provide improved stove which is capable of burning a variety of liquid fuels such as JP-8, diesel fuels or kerosene.




It is still further object of the invention to provide an improved stove which is easy to ignite, reliable to operate and easy to maintain.




It is still further object of the invention to provide an improved stove which can be refueled in the appliance and which does not have a pressurized fuel tank.




SUMMARY OF THE INVENTION




In accordance with these objects, there is provided, according to the invention, a stove apparatus having a frame with an interior opening. There is a burner mounted within the opening. The apparatus includes an air compressor mounted on the frame. There is an air conduit which extends between the compressor and the burner. A liquid fuel container is mounted on the frame within the opening. A fuel conduit extends between the container and the burner. A heat shield extends about the burner and separates the burner from the fuel container. A fuel control valve controls a flow of fuel from the fuel container to the burner. There is a control device for controlling output of the compressor.




In one embodiment, the apparatus has a movable front access panel and controls mounted on the access panel.




There may be a knob which simultaneously regulates the fuel control valve and speed of the compressor.




Preferably the compressor has a suction port. The apparatus then includes a suction conduit connecting the suction port to the fuel container and to a valve operatively connected to the suction conduit. The compressor can selectively draw fuel into the fuel container for refueling the stove.




The fuel container may have a vent body mounted thereon. The suction conduit is connected to the vent body. The vent body is mounted on top of the container and has a fuel tube extending to near the bottom of the container. There may be a float slidingly mounted on the tube and a first switch operatively connected to the compressor. The float has means for actuating a switch to stop operation of the compressor when fuel is near the top of the container.




In one preferred embodiment the body has means for preventing fuel from entering the suction conduit from the container. This includes a chamber having a top and a bottom. There is a check valve seat at the top of the chamber. A check valve ball, buoyant in the fuel, is movably mounted in the chamber. A conduit extends from near the bottom of the chamber to the container. If fuel is drawn into the chamber, the check valve ball floats to the top of the chamber and blocks the fuel from entering the suction conduit. For example, the valve seat may be conical in shape, tapering inwards towards the suction conduit. The chamber may have a frustum shaped portion adjacent the seat. The frustum shaped portion has walls tapering inwardly towards the valve seat which are less acutely sloped than the valve seat.




Stoves according to the invention offers significant advantages over the prior art. They utilize a non-pressurized fuel system which is inherently safer than a pressurized system. The stoves can be refueled in the appliances. They are also capable of burning JP-8 fuel or, alternatively, a variety of different fuels such as JP-8 fuels, military diesel fuels, kerosene or JP-5.




Stoves according to the invention also may include electronic ignition which facilitates starting of the appliance. They are easy to operate and reliable in operation. Warming up time is reduced from 30 minutes to 120 minutes in some prior art devices to approximately 2 minutes. The startup is smoke-free and they are capable of shutting off immediately without going through any elaborate shutdown procedure.











BRIEF DESCRIPTION OF THE DRAWINGS




In the drawings:





FIG. 1

is an isometric view of a stove according to an embodiment of the invention, the front panel thereof being shown in the open position;





FIG. 2

is a side elevation thereof;





FIG. 3

is a schematic diagram thereof;





FIG. 4

is a side view, partly broken away, showing the fuel regulator and fuel pickup tube thereof and a fragment of the fuel tank in ghost;





FIG. 5

is an isometric view thereof with the heat shield removed and the burner shown exterior to the frame;





FIG. 6

is an isometric view of the heat shield;





FIG. 7

is a front view thereof;





FIG. 8

is a sectional view of the control knob thereof;





FIG. 9

is a side view, partly in section, of the vent assembly for the fuel tank thereof;





FIG. 10

is an exploded view of the control panel thereof;





FIG. 11

is a front, isometric view of the control panel;





FIG. 12

is aside view, partly in section, of the compressor thereof;





FIG. 13

is a rear view thereof, partly in section and partly broken away;





FIG. 14

is an isometric, exploded view of the fueling assembly thereof;





FIG. 15

is a continuation of

FIG. 14

, showing the flame sensor, needle valve, solenoid for controlling the compressor and the knob of the control panel;





FIG. 16

is a front elevation of the battery pack thereof; and





FIG. 17

is a diagrammatic view of the fuel regulator thereof.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS




Referring to the drawings, and first to

FIGS. 1 and 2

, these show a stove


20


according to an embodiment of the invention. The stove has six sub assemblies, the first being frame assembly


22


, best shown in

FIGS. 1

,


5


and


6


, which includes frame


40


with an interior opening


41


, a fuel container


102


mounted on the frame within the opening, heat shield


103


and a reflector


105


mounted within cavity


107


in the heat shield.




The second sub assembly is burner assembly


24


, shown best in FIG.


5


and schematically in FIG.


3


. This includes an air aspiration, infrared burner of a type previously known and disclosed in U.S. Pat. No. 5,527,180. This burner utilizes a two-stage combustion process which recirculates combustion gases to achieve complete fuel vaporization. By recirculating the combustion products and re-burning the gases within the burner head


25


, the two-stage process burns virtually all of the hydrocarbons, approaching complete combustion. The benefits of a complete combustion are numerous, including maximum efficiency and heat transfer, no smoke and very low carbon monoxide emissions. When multiple stove units are used in an enclosed kitchen, near complete combustion is necessary to insure the health and safety of cooking staff. The infrared burner technology helps preserve clean breathable kitchen air.




The third sub assembly is the controller and associated wire harness assembly


26


shown in FIG.


10


and schematically in FIG.


3


.




The fourth sub assembly is compressor assembly


28


shown best in

FIGS. 12 and 13

. Compressor


68


provides compressed air for nozzle


69


of the burner assembly


24


, as shown in FIG.


3


. As discussed below, the compressor also serves to draw fuel into the fuel container.




The fifth sub assembly is fuel delivery block assembly


30


, shown in FIG.


14


. The sixth sub assembly is fuel level/vent assembly


32


shown best in FIG.


9


.




Referring to these sub assemblies in more detail, and first to sub assembly


22


, frame


40


, shown best in

FIG. 5

, is constructed chiefly of aluminum tubing welded together about opening


41


. In this embodiment there are three horizontal tiers of tubing, namely tiers


45


,


47


, and


49


. There is also a plurality of vertical members such as member


51


. Thus the frame is a perimeter frame in this example which extends about the central opening


41


.




Fuel container


102


, somewhat wedge-shaped in this example, is mounted on the frame within the opening. Manual filler cap


64


and fuel regulator


130


are mounted on one side of the container. Vent valve


62


is mounted on top


63


of the container. Heat shield


103


, together with reflector


105


, are mounted on top


109


of the frame by a plurality of bolts


111


in this example. The heat shield and reflector are of stainless-steel in this example.




Referring to

FIG. 5

, burner assembly


24


includes burner


42


with burner head


25


. When assembled, as seen in

FIG. 1

, the burner head


25


projects through opening


27


in the heat shield and is located within cavity


29


formed therein. It may be seen that the heat shield extends about the burner and separates the burner from fuel container


102


.




The burner is supplied with fuel by air aspiration type nozzle


69


as shown in FIG.


3


. The purpose of the nozzle is to transform liquid fuel into a finely atomized spray with increased surface area to promote mixing of the air and fuel and facilitate evaporation. Nozzle


69


is a twin fluid air-assist type nozzle, also known as a siphon type air atomizing nozzle. Introducing high velocity air into the slow-moving fuel causes the fuel to be disintegrated by the mechanical energy from the air. Additionally, the compressed air flows through the nozzle, creating a low-pressure area inside the nozzle cavity. This low-pressure is used to siphon the fuel from the container


102


through the fuel regulator and needle valve described below and the nozzle into the combustion chamber of the burner.




Compressor


68


supplies pressurized air to the nozzle through air conduit


71


. The nozzle siphons fuel from fuel container


102


through siphoning fuel line


103


.


1


and provides an atomized fuel spray


105


which is ignited within the burner. As mentioned above, this type of burner is known and is disclosed in U.S. Pat. No. 5,527,180. The burner utilizes a two-stage combustion process where the combustion products are re-circulated and re-burned, eliminating virtually all hydrocarbons and approaching complete combustion.




Compressor assembly


28


, including compressor


68


, is shown in

FIGS. 1

,


12


and


13


. The compressor is a single piston diaphragm compressor in this example, although other types of compressors or air pumps could be substituted in alternative embodiments. The compressor includes an electric motor


75


with an eccentric device


77


mounted on shaft


79


thereof. Rod


81


connects the eccentric device to intake disk


83


and compression disk


85


which are connected on opposite sides of diaphragm


87


by screw


89


. Rotation of the motor causes reciprocation of the rod and deflection of the diaphragm. There is also an integral accumulator


23


built in to head


25


.


1


and cylinder


27


.


1


.




There is an inlet reed valve


300


and an outlet reed valve


302


. The diaphragm goes down on intake and draws air through reed valve


300


. The diaphragm goes up on output and the compressed air is forced pass reed valve


302


. The accumulator volume dampens pulses resulting from this operation.




There is an air pressure adjustment screw


70


to adjust the air pressure. The screw bypasses high-pressure air from the high-pressure side to the low-pressure side. The compressor has an outlet


29


.


1


for pressurized air connected to conduit


71


and a suction outlet


33


connected to conduit


35


.




In this embodiment the fuel delivery nozzle


69


comprises part of fuel delivery block assembly


30


shown in FIG.


14


. It is connected to the burner to maintain concentricity so that the fuel spray remains in the center of the burner to minimize impingement on the burner. The nozzle is mounted on one side of block


61


thereof. There is a fuel needle valve


88


which meters fuel to the nozzle to control the rate of flow of fuel.




A feedback potentiometer


76


, shown in

FIG. 15

, controls the output of compressor


68


and thereby air pressure to the nozzle


69


. As the stove operates, fuel is siphoned from the fuel container through the fuel lines, the shut off solenoid


92


, shown in

FIGS. 3 and 14

, and the needle valve


88


to the nozzle


69


. The needle valve controls pressure drop across the metering orifice. This in turn controls the fuel flow to the nozzle. When control knob


72


is adjusted, two fuel flow parameters are altered simultaneously. These two fuel control parameters are arranged so that a linear fuel rate is maintained. This is accomplished by rotation of knob


72


which simultaneously controls the fuel supply to the burner via the needle valve and the compressor output via the feedback potentiometer.




As seen in the sectional view of

FIG. 8

, the knob


72


has a pair of projections


80


and


81


on inner face


83


. These are spaced apart and slidingly engage slots


84


and


86


in potentiometer


76


, shown in FIG.


15


. At the same time, the knob engages cap


87


of needle valve


88


. The needle valve has a male threaded stem


89


which engages corresponding female threads in block


61


. Therefore rotation of the knob rotates the valve stem, causing axial movement of the valve stem to control the flow of fuel to the nozzle. At the same time, the knob rotates the potentiometer to control the speed of the compressor such that the amount of air supplied to the nozzle is correct for the amount of fuel. The projections allow the knob to continue engagement with the potentiometer, while allowing axial movement of the valve stem by means of an axially compliant coupling.




A flame sensor


100


is also mounted on the block


61


shown in FIG.


15


. The flame sensor views the flame in the burner through an aperture


101


in the block


61


shown in FIG.


14


. The flame sensor is located immediately beside the nozzle


69


, optimizing the viewing angle. The view of the sensor is parallel to the axis of nozzle


69


.




The flame sensor measures the flare intensity and converts it to a DC voltage signal rather than steady state light. The sensor is designed to respond to changing light intensity rather than respond to steady-state light intensity. All flames have a characteristic changing light intensity or flicker frequency. The sensor is tuned to respond to a specific flame flicker frequency and ignore other sources of light intensities such as sunlight or fluorescent light. The sensor measures the flame intensity in the infrared spectrum. A threshold value for the DC signal is established. Over this threshold flame is present, below it no flame is present.




An ignitor


90


, also mounted on block


61


, ignites the air fuel mixture expelled from the nozzle. The ignitor is attached to the block


61


so its position relative to the nozzle and fuel spray is maintained. This is critical to ensure reliable flame ignition and longer ignitor life.




A fuel on/off solenoid valve


92


controls the flow of fuel to the nozzle through conduit


103


.


1


shown in FIG.


3


. Three-way, two position solenoid valve


94


selects between air filter


98


and the vent assembly


32


described below. This allows the suction outlet


33


of the compressor shown in

FIG. 12

to select between two operating modes. The first, with the valve in the normal position, is where air is drawn through air filter


98


for normal operation of the compressor to supply compressed air to the nozzle. The second mode, with the valve in the energized position, is to draw air from the fuel container


102


during the refueling operation described below.




The sixth sub assembly, namely fuel level/air vent assembly


32


, shown in

FIG. 9

, includes a vent body


62


mounted on top of the fuel container


102


. The suction conduit


35


from the compressor, shown in

FIG. 12

, is connected to fitting


110


shown in

FIG. 9

which is equipped with a check valve


124


. There is a solenoid valve


125


in the vent body which opens or closes the suction conduit. The valve opens to keep the fuel at atmospheric pressure when the stove is operational. During refueling, this valve is closed. It is also normally closed when the stove is non-operational. A suction conduit


122


extends between the solenoid valve and chamber


127


equipped with a fuel - resistant buoyant float


120


. The chamber communicates with the inside of the container through opening


129


. During refueling operations, suction is applied to the fitting


110


by the compressor, drawing air from the container and drawing fuel into the container through fuel line


131


shown in FIG.


2


. There is a quick connect fitting


133


on the fuel line adjacent front


135


of the stove. A hose from a fuel supply is coupled to this fitting during the refueling operation.




There is a vertical tube


48


, shown in

FIG. 9

, brass in this example, which extends downwardly from vent body


62


to a position near the bottom of fuel container


102


. A pair of floats


170


and


171


are slidingly mounted on the tube. An annular stop


174


keeps float


170


near the top of the rod, while stop


176


limits its upward movement. Likewise float


171


has upper and lower stops


180


and


182


. Each of the floats has a magnet


184


. There is an internal reed switch


186


inside tube


48


adjacent each of the floats (only one shown). The switch adjacent float


171


is activated when the float reaches the lower position as illustrated. This provides a signal to the processor that the fuel container is near empty. The switch adjacent float


170


is positioned so it is activated when the float reaches the upper position against stop


176


. This signals the processor that the fuel tank is full and stops the compressor.




If float


170


fails to signal the processor and stop the compressor, then spherical float


120


rises in chamber


127


as fuel fills the chamber. The float acts as a check valve ball and rises against check valve seat


190


at the top of chamber. It may be observed that the check valve seat is conical in shape, tapering inwardly towards suction conduit


122


. This shape allows the ball to seal the conduit, but inhibits the ball from sticking in that position. The conduit has a frustum shaped portion


192


adjacent to the seat. This portion has walls tapering inwardly towards the valve seat, but they are less acutely sloped than the valve seat. This causes a Venturi effect which draws the ball


120


upwardly towards the valve seat, helping it seat in position to prevent fuel from entering the suction conduit and the compressor.




There is a regulator


130


, shown in

FIGS. 1

,


4


and


17


, which compensates for the changing lift height as the fuel is consumed so that the nozzle suction pressure remains constant. This maintains a constant fuel flow as the fuel level in the fuel container changes. Fuel has mass. Therefore, if the fuel level is high it needs less suction to lift. More suction is needed as the fuel is consumed. The regulator compensates for this.




Referring to

FIG. 17

, the regulator


130


in this embodiment is adapted from a chainsaw regulator. It includes a diaphragm


200


and a needle valve


202


having a rubber tip


204


. There is a lever


206


mounted on a fulcrum


208


which engages the needle valve and the diaphragm. There is a coil spring


210


which biases the lever towards the diaphragm. Normally the spring counters atmospheric pressure. The needle valve is pushed down and seals inlet


212


. A vacuum however deflects the diaphragm. The atmosphere pushes downwardly and opens the inlet. The diaphragm has a sintered bronze filter


216


which keeps dirt out of the diaphragm.




The regulator opens and allows fuel to flow only when a vacuum is present in the fuel line. Air under pressure is supplied to the nozzle. The Venturi effect creates a vacuum for suction to the nozzle. When the compressor stops, the vacuum is lost and the regulator stops the flow of fuel.




There is a fuel filter


132


attached to inlet


133


of the regulator as seen in FIG.


4


. The filter insures that the fuel passing into the fuel system is clean and prevents clogging of the fuel nozzle.




The fuel regulator is mounted on a boss


135


on the side of the fuel container


102


. It is sealed by means of an O-ring


137


. Screws


139


attach the regulator to the fuel container. The regulator is mounted low on the fuel container to maximize its effectiveness in compensating for changing fuel level.




Controller assembly


26


, best seen in

FIG. 10

, is mounted on the back of door


50


which is hingedly mounted to the frame adjacent its bottom, allowing the door to pivot open as seen in FIG.


1


. There is a latch


51


, shown in

FIG. 11

, which normally keeps the door closed.




Controller


52


is a microprocessor built into the back of circuit board


53


.




The front of the door serves as a control panel as shown in

FIG. 11

including keypad


54


and indicator lights


58


. Thus the door provides two functions, front access to the interior of the stove and as controller packaging. The controller controls all electrical and process functions of the stove. It is microprocessor based. The micro-processor controls and modulates the input voltage and outlet as constant voltage to the components using PWM control. Each of the output circuits utilizes MOSFET style transistors with internal thermal protection to control the required devices.




LED panel


58


indicates to the operator flame hours and also error messages from internal diagnostics.




It will be understood by someone skilled in the art that many of the details described above are by way of example only and are not intended to limit the scope of the invention which is to be interpreted with reference to the following claims.



Claims
  • 1. A stove apparatus, comprising:a frame having an interior opening; a burner mounted within the opening; an air compressor mounted on the frame; an air conduit extending between the compressor and the burner; a liquid fuel container mounted on the frame within the opening; a fuel conduit extending between the container and the burner; a heat shield extending about the burner and separating the burner from the fuel container; a fuel control valve controlling a flow of fuel from the fuel container to the burner; a control device for controlling output of the compressor; and a manually operable device which simultaneously regulates the valve and speed of the compressor.
  • 2. An apparatus as claimed in claim 1, wherein the apparatus has a movable front access panel and controls mounted on the access panel.
  • 3. An apparatus as claimed in claim 1, wherein the manually operable device is a knob.
  • 4. An apparatus as claimed in claim 3, wherein the control device is a rotary device operated by rotation of the knob.
  • 5. An apparatus as claimed in claim 4, wherein the fuel control valve has a threaded valve stem, whereby rotation of the valve stem causes axial movement of the valve stem to control the flow of fuel, the valve stem being operatively connected to the knob, whereby rotation of the knob controls the flow of fuel.
  • 6. An apparatus as claimed in claim 5, wherein the knob has projections and the control device has slots which slidingly engage the projections, allowing axial movement of the knob with respect to the controller.
  • 7. An apparatus as claimed in claim 6, wherein the control device is a potentiometer.
  • 8. A stove apparatus, comprising:a frame having an interior opening; a burner mounted within the opening; an air compressor mounted on the frame, the compressor having a suction port; an air conduit extending between the compressor and the burner; a liquid fuel container mounted on the frame within the opening, the fuel container having a vent body mounted thereon, a first valve being mounted in the vent body; a suction conduit connecting the suction port to the fuel container, the suction conduit being connected to the vent body, the first valve selectively allowing communication between the container and the compressor; a valve operatively connected to the suction conduit, whereby the compressor can selectively draw fuel into the container; a fuel conduit extending between the container and the burner; a heat shield extending about the burner and separating the burner from the fuel container; a fuel control valve controlling a flow of fuel from the fuel container to the burner; a control device for controlling output of the compressor; and a vent body mounted on the fuel container, the suction conduit being connected to the vent body, the body having means for preventing fuel from entering the suction conduit from the container, the means for preventing including a chamber having a top and a bottom, a check valve seat at the top of the chamber, and a check valve ball, buoyant in the fuel, movably mounted in the chamber, whereby if fuel is drawn into the chamber, the check valve ball floats to the top of the chamber and blocks the fuel from entering the suction conduit.
  • 9. An apparatus as claimed in claim 8, wherein the first valve is a solenoid valve.
  • 10. An apparatus as claimed in claim 8, wherein the fuel container has a top and a bottom, the vent body being mounted on the top of the container and having a fuel tube extending to near the bottom of the container.
  • 11. An apparatus as claimed in claim 10, including a first float slidingly mounted on the tube and a first switch operatively connected to the compressor, the first float having means for actuating the first switch when fuel in the container is near the top thereof to stop operation of the compressor.
  • 12. An apparatus as claimed in claim 11, including a second float slidingly mounted on the tube and a second switch operatively connected to a signaling device, the second float having means for actuating the second switch when fuel in the container is near the bottom thereof to operate the signaling device and indicate that the container is near empty.
  • 13. A stove apparatus, comprising:a frame having an interior opening; a burner mounted within the opening; an air compressor mounted on the frame, the compressor having a suction port; an air conduit extending between the compressor and the burner; a liquid fuel container mounted on the frame within the opening; a suction conduit connecting the suction port to the fuel container; a valve operatively connected to the suction conduit, whereby the compressor can selectively draw fuel into the container; a fuel conduit extending between the container and the burner; a heat shield extending about the burner and separating the burner from the fuel container; a fuel control valve controlling a flow of fuel from the fuel container to the burner; a control device for controlling output of the compressor; and a vent body mounted on the fuel container, the suction conduit being connected to the vent body, the body having means for preventing fuel from entering the suction conduit from the container, the means for preventing including a chamber having a top and a bottom, a check valve seat at the top of the chamber, the valve seat being conical in shape and tapering inwardly towards the suction conduit, and a check valve ball, buoyant in the fuel, movably mounted in the chamber, whereby if fuel is drawn into the chamber, the check valve ball floats to the top of the chamber and blocks the fuel from entering the suction conduit.
  • 14. An apparatus as claimed in claim 13, wherein the chamber has a frustum shaped portion adjacent the seat.
  • 15. An apparatus as claimed in claim 14, where in the frustum shaped portion has walls tapering inwardly towards the valve seat which are less acutely sloped than the valve seat.
  • 16. A stove apparatus, comprising;a frame; a burner mounted on the frame, the burner having a nozzle; an air compressor mounted on the frame having an intake and an outlet; an air conduit extending between the outlet of the compressor and the burner; a liquid fuel container mounted on the frame within the opening; a fuel conduit extending between the container and the burner; a suction conduit connecting the intake of the compressor to the fuel container; a first valve which selectively opens the suction conduit to refuel the tank; a fuel delivery block, the nozzle and the first valve being mounted on the fuel delivery block; and a potentiometer for controlling the air compressor, the potentiometer being mounted on the fuel delivery block.
  • 17. A stove apparatus as claimed in claim 16, including a second valve which selectively opens the intake of the compressor, the second valve being mounted on the fuel delivery block.
  • 18. A stove apparatus as claimed in claim 17, including a third valve which controls fuel to the burner through the fuel conduit, the third valve being mounted on the fuel delivery block.
  • 19. A stove apparatus as claimed in claim 16, wherein the fuel container includes a vent for venting the container during stove operation.
  • 20. A stove apparatus as claimed in claim 16, including a solenoid valve which vents the fuel container during stove operation.
  • 21. A stove apparatus, comprising:a frame; a burner mounted on the frame, the burner having a nozzle; an air compressor mounted on the frame having an intake and an outlet; an air conduit extending between the outlet of the compressor and the burner; a liquid fuel container mounted on the frame within the opening; a fuel conduit extending between the container and the burner; a suction conduit connecting the intake of the compressor to the fuel container; a first valve which selectively opens the suction conduit to refuel the tank; a fuel delivery block, the nozzle and the first valve being mounted on the fuel delivery block; a second valve which selectively opens the intake of the compressor, the second valve being mounted on the fuel delivery block; a third valve which controls fuel to the burner through the fuel conduit, the third valve being mounted on the fuel delivery block; and a control device to vary compressor output.
  • 22. A stove apparatus as claimed in claim 21, wherein the control device is a potentiometer and the third valve is a needle valve.
  • 23. A stove apparatus as claimed in claim 22, including a mechanism for simultaneously adjusting the potentiometer and the needle valve.
  • 24. A stove apparatus comprising a burner having a siphon type air atomizing nozzle; a non-pressurized fuel system including a container, a fuel control valve, and a fuel siphon conduit connecting the fuel container to the nozzle via the fuel control valve, whereby the nozzle siphons fuel from the container; a compressor with variable output; a compressor control which regulates speed of the compressor; an air conduit which connects the compressor to the nozzle; and a burner control which simultaneously operates the fuel control valve and the compressor control, whereby, when burner output is adjusted by the burner control, fuel and air flow to the burner are simultaneously controlled so that the amount of air supplied to the nozzle is correct for the amount of fuel supplied to the nozzle.
  • 25. The stove apparatus as claimed in claim 24, wherein the burner control is manually operable.
  • 26. A stove apparatus comprising a burner having a siphon type air atomizing nozzle; a non-pressurized fuel system including a container, a fuel control valve, and a fuel siphon conduit connecting the fuel container to the nozzle via the fuel control valve, whereby the nozzle siphons fuel from the container; a compressor with variable output; a compressor control which regulates output of the compressor; an air conduit which connects the compressor to the nozzle; and a manually operable burner control which simultaneously operates the fuel control valve and the compressor control, the burner control being a rotary device whereby, when burner output is adjusted by the burner control, fuel and air flow to the burner are simultaneously controlled so that the amount of air supplied to the nozzle is correct for the amount of fuel supplied to the nozzle.
  • 27. The stove apparatus as claimed in claim 26, including a knob for manually rotating the rotary device and thereby simultaneously controlling air and fuel supplied to the nozzle.
  • 28. The stove apparatus as claimed in claim 27, wherein the knob has projections and the compressor control has slots which slidingly engage the projections, allowing axial movement of the knob with respect to the compressor control.
  • 29. The stove apparatus as claimed in claim 28, wherein the compressor control is a potentiometer.
  • 30. A stove apparatus comprising a frame having an interior opening; a burner mounted within the opening, the burner having an air aspiration type nozzle; a variable speed air compressor mounted on the frame; an air conduit extending between the compressor and the burner; a non-pressurized fuel system including a liquid fuel container mounted on the frame within the opening, a siphon fuel conduit extending between the fuel container and the nozzle and a fuel control valve controlling a flow of fuel from the fuel container to the burner; a heat shield extending about the burner and separating the burner from the fuel container; a control device for controlling output of the compressor; and a manually operable device which simultaneously regulates the fuel control valve and the speed of the compressor, whereby the amount of air supplied to the burner is correct for the amount of fuel supplied to the burner.
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Number Name Date Kind
3577877 Warne May 1971 A
3847537 Velie Nov 1974 A
3947218 Landis Mar 1976 A
4149842 Benjamin Apr 1979 A
4223692 Perry Sep 1980 A
4340362 Chalupsky et al. Jul 1982 A
4431382 Edman et al. Feb 1984 A
5080580 Clapp Jan 1992 A
5527180 Robinson et al. Jun 1996 A
5927961 Robinson et al. Jul 1999 A
Foreign Referenced Citations (1)
Number Date Country
0 328 418 Aug 1989 EP