US3070150A - Liquid fuel heater - Google Patents

Description

Dec. 25, 1962 R. H. HUNTER ETAL. 3,070,150

LIQUID FUEL HEATER Filed May 21, 1958 INVENTORS EOBEQT H. HUNTER BY HAQQ/S SIVI/TH ATTOQNEYS.

United States Patent Office LIQUID FUEL HEATER Robert H. Hunter, Gates Mills, and Harris W. Smith, llainbnidge, Ohio; said Smith assignor to said Hunter Filed May 21,1958, Ser. No. 736,829

4 Claims. (Cl. 1584) This invention relates to heating devices, more particularly to atomizing oilburners of the type in. which both combustion supporting air and liquid fuel oil are supplied to a nozzle system, the air being supplied under pressure to entrain the fuel for discharge from a common orifice in the form of a combustible spray mixture.

Oil burning heaters are frequently required to operate elficiently on oils of difierent types and 'viscosities, at differentfiring rates and under greatly varying climatic conditions. A number of burner designs have evolved as a result of attempts to provide systems capable of being fired at different rates and also capable of burning different oils without adjustment. One such burner is disclosed in copending application Serial No. 515,686 filed June 15, 1955 by Robert H. Hunter, one of the present applicants, and. Ralph S. Damon, now United States Patent 2,876,763, dated March 10, 1959, owned by the assignee of the present application.

The principal object of the invention is to provide an improved oil heater of the character referred to, particularly a simplified arrangement for effecting complete and thorough mixing of the air and fuel oil over a wide air pressure range.

V More specifically, the invention is concerned with confinement of the projected spray to maintain control of the resulting flame, minimize pulsations and vibrations and obtain high efficiency. .Such control is another objective and. is achieved by projecting the fuel-air spray across a cushion chamber and thence directly into one end of a hollow member in the form of a cylindrical open ended combustion tube suitably supported on the nozzle axis in concentric relation to the spray-path. The receiving end of the combustion tube is spaced axially from the discharge orifice of the nozzle. Suitablewalls, which Patented Dec. 25, 1952 2 embodiment is illustrated in the accompanying drawings forming a part of the specification.

In-the drawings: i FIG. 1 is a fragmentary isometric drawing partly in axial section and with parts broken away and removed showing the heating device of the present invention;

- FIG. 2 is an enlarged fragmentary longitudinal section through the nozzle assembly of the device of FIG. 1; and e FIG Q3 is a transverse sectional details taken through the nozzle assembly substantially in the-plane represented by the line 3-3 of FlG. 2. i The heatingdevice of the present invention is essentially an oil burner and as such may be used in various conventional and well known ways. The hot gases and products of combustion can be conducted through a suitable heat exchanger to exhaust and thus used to heat air supplied to a building through such exchanger. In another application the hot gaseous products of combustion may be passed directly into a space to be heated such as a retort or kiln as employed in various processing industries.- As an aid to the cold starting of an internal combustion engine the present heater may discharge directlyinto the intake manifold of such an engine.

The present heater comprises casing means which in,- cludes tubular shell 1, housing 4 andextension tube 5, {an hollow circular sectioned components disposed in end to end relation and concentric to the main axis ofthe device. 0 The shell 1 may take the .form of a cylindrically shaped brass or iron casting. The ends of this shell have reduceddiameter portions 2, 3 that are respecdesirably may constitute a supporting means for the combustion tube, define and enclose a cushion chamber which is of greater transverse dimension than the diameter of the combustion tube, the cushion chamber incorporating the space between the discharge orifice of the nozzle and the receiving end ofthe combustion tube. Suitable passages and ports are provided in the cushion chamber walls and support means to supply secondary air to the cushion chamber, preferably at its outer periphery, so that such secondary air mingles with or is drawn into the spray as the latter enters the combustion tube.

Another object of. the invention is concerned with control over the recirculation of gases within a combustion tube such as described above. To this end a control ring comprising a cylindrical annulus is mounted within the combustion tube in coaxial relation. The external diameter of such control ring is less than that of the interior of the combustion tube and suitable spacers are interposed between the ring and the tube to support the latter in predetermined relation spaced from both ends the best knownmode of practicing the invention This v tively received telescopically one within one end of the housing 4" and the other within the rear end of thecylindrical extension tube 5 into which the products of combustion, are discharged. The ends of the housing 4 andtheextension tube 5 abut radial shoulders 6 on the shell 1, thereby locating .the parts, in assembly,,and are secured by suitable means such as 'drive screws, not shown. i l

Theextension tube 5 may be secured to and open into, for example, the intake manifold .of a diesel or other internal combustion engine. Thus the heater may be supported by such manifold to discharge hot gases and products of combustion into the manifold where they will. comingle with and heat air moving into the cylinders of the engine. In another arrangement theextension tube 5 may be suitablysupported and connected to a, heat exchanger through which the hot gases and products of combustionof the heater are caused to flow in a conventional manner. In other arrangements the extension tubeS', suitably lengthened and supported, may be made to discharge the hot gases and products of combustion into the interior of a kiln, retort or other space or device to be heated. f e e The housing, 4 has acylindrical wall 7 and, at the rear end of the later,an end closure wall 8 which is normal tothemain axis and is formed with acentral opening 10 .(FIG. 2) closed by a nozzle structure 11.

While it is feasible to ignite the fuel-air spray in an open combustion chamber such as provided by the housing 4, shell 1 andextension tube 5 comprising the casing means, improved efficiency, and control and better heatingis achievedby confining the spray within a hollow member in the form of a generallycylindrical combustion tube 20 open at both ends. The combustion tube ,is supported in coaxial relation to the path or trajectory of the fuel spray and is positioned with its receiving end spaced axially from thenozzle so as to provide an intervening cushion air chamber through which secondary air is fed to the spray and which has a modulating effect on the I flame that minimizes pulsations and vibrations. To this end a specialized internal partitioning arrangement is provided within the housing 4. A pair of axially spaced cross walls orpartitions 12, 13, each in the form of a circular ring, and a cylindrical inner Wall 14, extending between the cross walls, define a cushion chamber 15 across which the fuel-air spray from the nozzle 11 is projected. The housing 4 is desirably made as a casting of brass, aluminum, bronze or similar suitable metal. The cylindrical interior Wall surface terminates at a radial shoulder 17 against which the outer periphery of thecircular partition 12 is locatingly abutted in assembly. The shoulder 17 is spaced from the end closure wall 8 so that anarrow air chamber 18 is provided between thewalls 8 and 12.

The inner cylindrically shaped annular wall 14 is formed integrally with or at its rear end welded to the front face of thecircular partition wall 12 so as to be supported by the latter in concentric relation to theouter wall 7 of the housing and to the main axis of the device. Since the wall 14 is of less external diameter than the internal diameter of theouter wall 7, there is provided anannular air chamber 19 which surrounds the cushion chamber 15.

The rear face of thecircular partition 13 is engaged by the forward end of the inner annular Wall 14. The periphery of the other or front side of thepartition 13 is disposed against the end of the casing shell 1. Thus thepartition 13 is held in place against axial movement. Bothpartitions 12 and 13 have circular peripheries of approximately the same diameter as the machined internal cylindrical surface of thehousing wall 7 so that the parts are fixed in predetermined radial positions relative and concentric to the main axis of the device. Thus a circular centrally located axial opening through thepartition 13 into the receiving end of the hollow member orcombustion tube 20 is in the trajectory of the fuel-oil spray projected across the cushion chamber 15 from the nozzle assembly 11.

Thecombustion tube 20 is mounted cantilever fashion on and supported solely by thecircular partition 13 from which the tube projects forwardly through the center of the casing shell 1. Its base or receiving end is received over the central opening of the partition and is Welded or otherwise made fast thereto. The forward or discharge end of the combustion tube is formed with a circular inwardly directed curvedradial flange 21 which definescircular discharge opening 22.

Within and concentric to thecombustion tube 20 and spaced axially from both of its ends is a flame controlling sleeve 24 symmetrical about the axis of the device. This sleeve comprises a cylindrical, radially thin metal member which has an external diameter less than the internal diameter of thecombustion tube 20 in the provision of circumferentially extending clearance space 25 of greater axial than radial extent. The diameter of the clear opening through the sleeve is preferably greater than that of the discharge opening 22. The control sleeve is centered in the combustion tube by a number ofspacing blocks 26 distributed about the circumference of the sleeve and welded against the outside surface of the sleeve before the latter is slipped into the combustion tube. One or more of the spacing blocks are then welded to the combustion tube to secure the sleeve and tube in desired axial relationship.

The nozzle structure 11 is described and claimed in copending application for patent Serial Number 99,191, filed March 29, 1961. It comprises inner and outer tubular body members28, 29 and plugs ororifice members 41, 42, 43. The body members are disposed one within the other and are separated by anannular air chamber 30. The ends of thechamber 30 are closed by inwardly directedcircular flanges 32, 33 integrally formed on the outer member and which closely embrace cylindricalouter surface 34 of theinner member 28 at the ends of the latter. Thebody members 28, 29 are turned from brass or other suitable metal and-the circularjoints where thesurface 34 of the inner member is embraced by the inner peripheries of theend flanges 32, 33 are sealed as by brazing.

Anannular ring 35 surrounds and is brazed to the forward end of theouter member 29 adjacent the end flange 33 and is apertured at circumferentially spaced points to receive attachingscrews 36 which are threaded into the end wall 8 of the main housing 4 to secure the nozzle assembly in place over the circular opening lit.

Theinner body member 28 is longer than theouter member 29, projecting axially beyond the end flange 33 of the latter, across thenarrow air chamber 18, and being received within a shallowaxial flange 37 on thepartition 12. Acircular opening 38 in thepartition 12 registers With a counterbore 39 in the end of theinner body member 28, these openings constituting the outlet of the nozzle into the cushion chamber 15.

The plugs ororifice members 41, 42 and 43 are disposed in alignment within the hollow interior of the tubularinner body member 28. These members are each of circular cross section and are suitably held in axially spaced fixed relation coaxial to one another and to thetubular members 28, 29. A convenient structural arrangement comprises external threads all of the same diameter on the circular sectionedmembers 41, 42, 43 and matching internal threads on thebody member 28 throughout the entire length of its axial bore. The orifice plug thus may be screwed into desired positions in the bore of the body member.

Thefirst orifice member 41 has an axial throughpassage 45 terminating at the forward end of the member in a discharge orifice 46. At its rear end themember 41 is 'counterbored and tapped at 47 to receive threaded fitting 50 on the end of afuel supply line 59. Fuel oil, such as kerosene or gasoline, is contained in a suitable remote storage vessel or tank and supplied as by gravity flow to thepassage 45 of theorifice member 41 through a suitable flow control system such as a constant level float bowl device (not shown) which has a needle valve actuated by a float to maintain a constant level in the bowl. The bowl of the constant level fuel control device is connected to thepassage 45 through a short conduit such that the level in the bowl is substantially the same as or only slightly below the level of the orifice 46.

The plug or orifice members are formed on their confronting ends with coaxial surfaces of revolution which shape the aspirating chambers of the nozzle. Thus theorifice members 41 and 42 are formed with external or outwardly facing concave tapering surfaces ofrevolutions 48, 49 which are concentric to the axis or path .of fuel traveling through the nozzle device and approach such path tangentially. An internal or inwardly facing convexly curving taperedsurface 51 on theorifice member 42 is disposed in axially spaced relation to thesurface 48 of theorifice member 41, providing between theorifice members 41, 42 a first aspirating orair chamber 52 which surrounds and is coaxial to the fuel path and progressively diminishes in cross-sectional area in the direction of fuel flow. The smoothly curvingwall 51 of thechamber 52 blends tangentially into the Wall of anaxial passage portion 53 in the forward part of theorifice member 42. Thepassage 53 terminates in adischarge ggifice 54 spaced axially beyond or forward of the orifice An internal conxely curved tapered surface 55 is formed on theorifice member 43 and faces rearwardly, confronting the taperedsurface 49 of thesecond orifice member 42 in axially spaced relation, thus providing between themembers 42, 43 a second air or aspiratingchamber 56 which surrounds and is coaxial to the path of fuel advancing through the nozzle structure. Thechamber 56 progressively decreases in diameter and cross-sectional area toward an annular axially directed orifice 57 defined by a circular wall opening in the forward end of theorifice member 43 and the smaller diameter circular end of thesecond orifice member 42 which projects slightly through and is concentric to such wall opening in thethird orifice member 43. Front end face 58 of theorifice member 43 may be flat or, asshown, may be slightly dished or concave with the circular opening which defines the annular orifice 57 1ocated at'the bottom of the concavity. i

A number ofoblique passages 61, 62 are drilled or otherwise formed in the nozzle member 23 to place the annular air chamber 3i) in communication with each of the taperingair chambers 52, 56 at the rear or large diameter ends of the latter.

Air is supplied to theannular chamber 30 from a suitable source such as a centrifugal blower or fan (not shown) at a pressure of from about 1 to about 30 or more inches of water, the exact pressure depending upon factors such as fuel oil viscosity and the desired rate of fuel consumption. The air pressure is increased to increase the rate or with higher viscosity fuel oil and is decreased to decrease the rate or with lower viscosity fuel oil. The air is conducted from the blower or other supply through suitable conduit means which includes atubular conduit 63 brazed orotherwise secured totheouter member 29 of the nozzle structure. Theconduit 63 is disposed so that air forced into thechamber 30 enters tangentially throughopening 64 and flows about theinner nozzle member 28 in a clockwise directionas viewed in FIG. 3. The pressurized air thus introduced into the annular chamber is forced tangentially into the rear or closed ends of the taperingair chambers 52 56 through theoblique passages 61, 62; so that the air rotates in the tapered chambers in the same direction it rotates in theouter chamber 30, but ata higher velocity resultingfrom the reduced cross-sectional area. The high velocity air thus traveling through thefirst air chamber 52 and approaching the fuel path tangentially, generally from left to right as viewedin FIG. 2, has an aspirating eflect on the liquid fuel supply system, the reduced pressure which prevails in thechamber 52 and at the discharge orifice 46 results in fuel being drawn or projected into the chamber from such orifice. The projected fuel is comminuted and entrained in the high velocity air advancing helically and as a contracting cone into and through theaxial passage 53 of thesecond orifice member 42 so that the mixture is projected from theorifice 54 as a fine spray into and across the cushion chamber 15.

The circular opening in the end wall 8 of the main housing is larger than the external diameter of theinner body member 28 of the nozzle structure to allow air to flow into theair chamber 18 from thechamber 30 through a number ofports 65 formed in the flange 33. Prefera ably, the flange is canted to project through the wall opening It or theports 65 are otherwise made oblique to direct the air outwardly. At circumferentially spaced points located radially outwardly of the annular wall 14 thepartition 12 is formed withaxial ports 66 which place thechamber 18 in communication with theannular chamber 19 to supply pressurized air tothe latter. Radial ports 67 in the wall 14 andaxial ports 68 in theWall 13 place the cushion chamber and the interior of the shell 1 in communication with theannular chamber 19, the ports of each group being circumferentially spaced uniformly about the axis of the device. Thus air supplied under pressure to the annular chamber 39 in the nozzle struc ture through the supply tube orconduit 63 is distributed to a number of supply points along the path of the fuelair spray and the flame. Pressurized air in theannular chamber 19 surrounding the cushion chamber, such air being supplied through thenarrow chamber 18 and theports 65 and 65 is introduced radially into the cushion chamber through the ports 67 at a number of points spaced circumferentially about such cushion chamber and is also supplied through theaxial ports 68 to the annular space in the main shell l which surrounds thecombustion tube 20.

The air introduced into the cushion chamber 15 through 6 the ports 67 flows radially inward and mixes with the conical spray being projected continuously across the cushion chamber into the receiving end of thecombustion tube 20 from theorifices 54, 57 of the nozzle assembly. The system thus provides a center rich fuel-air mixture conducive to efficient burning with minimum smoking and depositionof carbon to the metal parts of the burner.

Ignition of the fuel-air spray is efiectedl by a high fre quency electrical spark produced betweencenter electrode 70 of a spark plug assembly 71 and one of the grounded metal parts such as the control sleeve 24 of the combustion tube assembly. In the arrangement shown, the spark plug assembly includes a threadedsupport sleeve 72 screwed into a tapped radial hole in the casing 1. The spark plug has an internal insulator or porcelain and an outside metal tube orsleeve 73 which extends radially across the annular chamber that surroun-ds'the combustion tube 20 and projects into the interior of the latter through ahole 74, a suitable annular clearance separating thesleeve 73 from the metal of thecombustion tube. Theelectrode 70 extends through theinternal porcelain insulator which is inside themetal sleeve 73 and at its outer end the electrode is threaded and provided with nuts or other suitable connector means for attachment of a high tension electrical cable 75 by means of which the spark plug is connected to one of the terminals of a suitable source of high frequency electrical curent, The other terminal of'the current source is grounded to the metal casing of the oil burner device so that, upon energization of the ignition system the desired spark is produced inside the tube Ztl.

Thus the present invention provides a compact, economical heater which incorporates a nozzle assembly operating on the aspirating principle and capable of atomizing fuel at a variable rate depending upon the pressure at which air is supplied through thetube 63 Since the entire air supplyis furnished through the single tube, variation in the pressure of the air so supplied automatically varies the rate of air supply to the several air chambers of the burner and to the difierent points along the fuel, air and flame path.

Prior to entering the cylindrically shaped combustion zone within thecombustion tube 20 the fuel-air spray travels across the cushion chamber 15 which is of larger cross-sectional area than the combustion zone and is symmetrical about the fuel path. At the discharge end of thecombustion tube 20, theflange 21 constitutes a choke on the flame and promotes a limited recirculation of the outermost portions of the gases in the tube. These outermost portions of the gases thus traveling rearwardly toward the receiving end of the combustion tube pass through clearance 25 between the control sleeve 24 and the internal surface of the combustion tube for reentry into the main body of the flame substantially at the receiving end of the combustion tube.

In accordance with the patent statutes the principle of the present invention may be utilized in various ways, numerous modifications and alterations being contemplated, substitution of parts and changes in construction being resorted to as desired, it being understood that the embodiment shown in the drawings and described above is given merely for purposes of explanation and illustration without intending to limit the scope of the claims to the specific details disclosed.

What we claim and desire to secure by Letters Patent of the United States is:

1. In a liquid fuel burner, a casing having an annular wall forming a combustion chamber, nozzle means fixed relative to the casing and adapted to receive fuel and air and project them into the chamber along a predetermined axis, a hollow member having an open receiving end, means mounting the member within the casing with said open end facing and disposed in spaced aligned relation to the nozzle means and with the member generally symmetric relative to said axis, said member being disposed-to receive the projected fuel and air in its open end, with the interior of said member constituting an initial combustion zone, said hollow member being of smaller cross. sectional area than and being separated from the casing by a surrounding annular clearance space, the casing being of greater length along said axis than the hollow member and having a combustion chamber portion beyond the member and continuous with the clearance space about the entire circumferential extent of the latter, means defining a cushion chamber including annular wall means surrounding the space between the nozzle means and the hollow member, said cushion chamber being of greater cross-sectional area than the interior of the hollow member and of greater dimension transverse to said axis than along said axis from the nozzle means to the open receiving end of the hollow member, air conducting means adapted to feed a first supply of air to the cushion chamber through the annular wall means at a plurality of points spaced circumferentially about the axis to flow first into the outer periphery of the cushion chamber and thence toward the center thereof, and said air conducting means feeding a second supply of air other than the air supplied to the cushion chamber to said annular clearance space to flow therein toward and into said combustion chamber portion in the same general axial direction as projected fuel and air.

2. In a burner as defined in claim 1 the hollow member being of metal and having on its other end an inturned flange of thin section defining a flame discharge orifice concentric with said axis and of less cross-sectional area than the combustion zone.

3. In a burner as defined in claim 1, a cylindrical sleeve of less axial length than diameter and also of less axial length than the hollow member, means supporting the sleeve within and in symmetrical spaced relation to the hollow member, and one end of the sleeve being closer to the receiving end of the hollow member than its other end is to the other end of the hollow member, said space between the hollow member and the sleeve constituting a return path over which gases circulating in the combustion zone flow toward the receiving end of the hollow member.

4. In a burner as defined in claim 1 said air conducting means comprising a portion of the casing surrounding the annular wall means in coaxial relation and separated therefrom by a second annular clearance space, said air conducting means also comprising a ring surrounding the receiving end of the hollow member and extending radially outward to the casing, said ring constituting a partition between the first mentioned and said second annular clearance spaces, and said ring being formed with openings communicating the said annular clearance spaces at circumlerentially spaced points for supplying air to said first mentioned annular clearance space from the second clearance space.

References Cited in the file of this patent UNITED STATES PATENTS 1,641,581 Egan Sept. 6, 1927 1,826,776 Gunther Oct. 13, 1931 1,869,897 Hyrner Aug. 2, 1932 1,989,421 Kerrick Jan. 29, 1935 2,047,570 Wiltshire July 14, 1936 2,050,577 Littleton Aug. 11, 1936 2,240,161 Mueller Apr. 29, 1941 2,623,786 Wille Dec. 30, 1952 2,701,608 Johnson Feb. 8, 1955 2,857,961 Brown Oct. 28, 1958 2,867,270 Brozozowski Ian. 6, 1959 FOREIGN PATENTS 1,111,865 France Nov. 2, 1955 1,129,673 France Sept. 10, 1956 1,157,143 France Dec. 23, 1957

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