US2778616A - Means for atomizing liquids, particularly for lubricating sheet metal during rolling - Google Patents

Means for atomizing liquids, particularly for lubricating sheet metal during rolling Download PDF

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US2778616A
US2778616A US473713A US47371354A US2778616A US 2778616 A US2778616 A US 2778616A US 473713 A US473713 A US 473713A US 47371354 A US47371354 A US 47371354A US 2778616 A US2778616 A US 2778616A
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inner tube
tube
annular chamber
bore
air
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US473713A
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Turpin Geoffrey Edgar
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Steel Company of Wales Ltd
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Steel Company of Wales Ltd
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B21MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
    • B21BROLLING OF METAL
    • B21B45/00Devices for surface or other treatment of work, specially combined with or arranged in, or specially adapted for use in connection with, metal-rolling mills
    • B21B45/02Devices for surface or other treatment of work, specially combined with or arranged in, or specially adapted for use in connection with, metal-rolling mills for lubricating, cooling, or cleaning
    • B21B45/0239Lubricating
    • B21B45/0245Lubricating devices
    • B21B45/0248Lubricating devices using liquid lubricants, e.g. for sections, for tubes
    • B21B45/0251Lubricating devices using liquid lubricants, e.g. for sections, for tubes for strips, sheets, or plates
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B21MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
    • B21BROLLING OF METAL
    • B21B45/00Devices for surface or other treatment of work, specially combined with or arranged in, or specially adapted for use in connection with, metal-rolling mills
    • B21B45/02Devices for surface or other treatment of work, specially combined with or arranged in, or specially adapted for use in connection with, metal-rolling mills for lubricating, cooling, or cleaning
    • B21B45/0203Cooling
    • B21B45/0209Cooling devices, e.g. using gaseous coolants
    • B21B45/0215Cooling devices, e.g. using gaseous coolants using liquid coolants, e.g. for sections, for tubes
    • B21B45/0233Spray nozzles, Nozzle headers; Spray systems
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10STECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10S261/00Gas and liquid contact apparatus
    • Y10S261/76Steam

Definitions

  • This invention relates to means for atomising liquids, particularly for lubricating sheet metal during rolling.
  • an atomising device comprising a hollow-walled tubular barrel, a casing disposed outside said tubular barrel forming an outer conduit surrounding said barrel, a compressed air inlet connection at one end of said outer conduit, transfer connection means at the other end of said outer conduit leading into the adjacent end of the bore of the tubular barrel, an injection device for delivering liquid into said bore longitudinally at a position adjacent the transfer connection means, so that heated 'air from the outer conduit is charged with liquid globules and then flows back along the bore of the tubular barrel to that end thereof adjacent the said one end of the outer conduit, and delivery means for the heated spray-laden air at that end of the bore, the hollow Wall of the tubular barrel being provided with inlet and outlet connections for heating fluid.
  • the invention to provide an improvement in or modification of this form of device, whereby better atomisation of the liquid is achieved.
  • the improved device moreover, is capable of operating satisfactorily under higher delivery pressures than the previous construction.
  • an atomising device comprising a hollow-walled tubular barrel through the wall of which a heating fluid is passed, a casing disposed outside said tubular barrel forming an outer conduit surrounding said barrel, a compressed air inlet connection at one end of said outer conduit, transfer connection means at the other end of said outer conduit leading into the adjacent end of the bore of the tubular barrel, an injection device for delivering liquid into said bore longitudinally at a position adjacent the transfer connection means, so that heated air from the outer conduit is charged with liquid globules as it flows back along the bore of the tubular barrel to a mixture outlet at the far end of said bore
  • injection and mixing means within the bore of the tubular barrel comprise a liquid injection nozzle directed along said bore-and a plurality of air nozzles fed with heated air from the outer conduit and arranged to discharge said air at positions posterior to the liquid nozzle.
  • the delivery orifices of the air nozzles are disposed at a plurality of positions along the bore of the tubular barrel.
  • the air nozzles may comprise tubular stems mounted in a partition extending across the bore of the tubular barrel.
  • the air nozzles can all extend parallel with the axis of the tubular barrel and are arranged as a circular array disposed around the liquid injection nozzle.
  • the air nozzles comprise tubes having their end portions partially flattened to form slot-like delivery orifices, these preferably being arranged radially.
  • the liquid injection nozzle may comprise a jet tube having an axial duct along which the liquid flows, an axially adjustable needle valve member being arranged It is an object of ICC to cooperate with an annular shoulder in said duct to regulate the flow of liquid therealong; the needle valve member may be fitted into the jet tube, said jet tube and valve member being removable as a unit from the tubular barrel.
  • Figure l is a diagram in the form of a longitudinal section to show the general arrangement of the improved atomising device and the various fluid spaces and passages therein;
  • Figure 2 is a transverse sectional elevation of a practical embodiment, the section being taken to correspond with the line 2-2 of Figure l and being drawn to an enlarged scale;
  • Figure 3 is a fragmentary longitudinal sectional elevation taken on the line 33 of Figure 2, and showing the air and liquid nozzles.
  • the atomising device shown in Figure 1 is used primarily for spraying palm oil on to sheet metal while it is being rolled. Palm oil is solid at ordinary temperatures but it can be melted and by using the appropriate form of atomiser it can be converted to a fine mist which is suitable for spraying on the sheet metal so as to produce a very thin uniform coating of palm oil thereon prior to rolling.
  • the device comprises a straight inner tube 10 which is surrounded by an intermediate tube 11, the two being connected at their ends so as to form a hollow-walled barrel, the annular chamber thereof being indicated at 12.
  • the chamber forms a heating jacket which is fed with steam through an inlet 13, said steam passing along the chamber 12 from left to right and being exhausted through a steam outlet 14.
  • An outer casing 15 is fitted around the tubular barrel 1%, 11 and is also closed at its ends to form an outer conduit 16 which is of annular shape in cross section. At its left-hand end it has an inlet 17 for compressed air, While at its right-hand end it leads into a number of radial passages forming transfer means, two of these passages being shown at 18 in Figure 1.
  • This partition 21 supports four air nozzles in the form of small diameter tubes which extend longitudinally of the bore 20, only two of said tubes being shown at 22. These tubes are fed with air from' the compartment 19 and as they are of different lengths they serve to deliver said air at different positions along the bore of the inner tube 10.
  • the liquid inlet is shown at 24 and leads into a chamber 25 from which a jet tube 26 extends axially through the compartment 19 and partition 21, said jet tube terminating just beyond said partition.
  • An adjustable needle valve 27 is provided in connection with the chamber 25 so as to enable the flow of liquid to be regulated closely to suit requirements.
  • the inner tube 10 leads to a delivery outlet28 which is conveniently in the form of an elbow or other pipe.
  • the steam which is circulated continuously through the chamber 12 causes the tubes 10 and 11 to be maintained in a heated state.
  • the compressed air as it travels along the outer conduit 16 becomes heated so that as it issues from the air nozzle 22'it readily breaks up the liquid spray which is being injected into the bore 20 from the jet tube 26.
  • the air nozzles are so constructed as to produce considerable turbulence within the bore 20 so that the mixture becomes further heated as it flows along the internal wall of the tube It), so that the product which is delivered through the outlet 28 is in a finely mixed anduniform state.
  • the partition 21 is fitted into the end of the tube and is formed with a tubular extension 29, which is in turn secured within a bore formed in a body 31, the bore 38 constituting the compartment 19.
  • the body 31 is enlarged in diameter and is formed with two shoulders 32 and 33 which serve for locating the ends of the intermediate tube 11 and the outer casing 15.
  • It also has a number of longitudinal passages 34 which communicate with the annular chamber 12 inside the intermediate tube 11 and connects said chamber to the interior of an annular cap 35 having the steam outlet 1 formed on its lower part.
  • the radial passages 18 are drilled at positions intermediate the longitudinal passages 34 and thus form the interconnecting means between the outer conduit 16 and the compartment 19.
  • the body 31 has an axial bore 36 into which a liquid jet tube 37 fits snugly, said tube having its forward end extending axially through the compartment 19 and through a hole 38 formed centrally in the partition 21, its delivery orifice 39 being substantially flush with the left-hand face of said'partition.
  • the jet tube 37 is enlarged in diameter at its right-hand end and is formed with a screwthread 48 by which it is secured in the body 31.
  • the jet tube 37 has an axial duct 41 terminating in an annular shoulder 42, which cooperates with the tapered end 43 of a needle valve member 44, the latter having a stem portion 45 which is screw-threaded into the jet tube and is provided with an adjusting knob 46; a lock-nut 47 serves to hold the desired adjustment.
  • the jet tube 37 Adjacent the screw-threaded portion 40, the jet tube 37 has a number of radial passageways 48 which communicate with an annular groove 49 in the body 39 and thus serve for feeding liquid from the liquid inlet 24 past the shoulder 42 to the axial duct 41 and delivery orifice 39.
  • the air jet tubes 22 are set into the partition 21 and are of different lengths so that the air from the compartment 19 is delivered at high velocity to diiferent points along the length of the bore 20.
  • the four tubes 22 can advantageously be about 2, 4, 6 and 8 inches long respectively
  • each has its end partially flattened to form a slot-shaped delivery jet orifice 5d, the slots being arranged radially as seen in end view.
  • the ends of the tubes are preferably cut off obliquely as indicated at 50:: in Figure 3.
  • the unit is conveniently provided with a socket 51 into which a pressure gauge 52 ( Figure 1) can be fitted to show the air pressure which is being fed to the air jet tubes 22.
  • An apparatus for producing a spray of atomised liquid, such as heated palm oil comprising an inner tube, an oil injection nozzle disposed within one end of said inner tube, spray delivery means at the other end of said inner tube, an intermediate tube surrounding the inner tube but spaced therefrom to form an intermediate annular heating jacket, means for passing heating fluid along said heating jacket, an outer tube surrounding the intermediate tube but spaced therefrom to form an outer annular chamber which is of small radial thickness and is shorter in axial length than the heating jacket, said outer annular chamber being carried wholly upon the outside of the intermediate tube, means for feeding compressed air into the outer annular chamber at that end thereof adjacent the delivery end of the inner tube, transfer conduit means forming a connection for compressed air extending inwards from the outer annular chamber, a multiple nozzle device which is disposed in the bore of the inner tube adjacent the inlet end thereof, and which comprises a wall closing the bore of said tube, a plurality of air nozzle tubes mounted in the wall and directed towards the delivery end of said inner tube, the delivery ends of said air atom
  • An apparatus for producing a spray of atomised liquid, such as heated palm oil comprising an inner tube, an oil injection nozzle disposed within one end of said inner tube, spray delivery means at the other end of said inner tube, an intermediate tube surrounding the inner tube but spaced therefrom to form an intermediate annular heating jacket, means for passing heating fluid along said heating jacket, an outer tube surrounding the intermediatetube but spaced therefrom to form an outer annular chamber, which is of small radial thickness and is shorter in axial length than the heating jacket, said outer annular chamber being carried wholly upon the outside of the intermediate tube, means for feeding compressed air into the outer annular chamber at that end thereof adjacent the delivery end of the inner tube, transfer conduit means forming a connection for compressed air extending inwards from the outer annular chamber, a multiple nozzle device which is disposed in the bore of the inner tube adjacent the inlet end thereof, and which comprises a wall closing the bore of said tube, a plurality of air nozzle tubes mounted in the wall and directed towards the delivery end of said inner tube, said air nozzle tubes being

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Nozzles (AREA)

Description

Jan. 22, 1957 E, TURPIN 2,778,616 MEANS FOR ATOMIZING LIQUIDS, PARTICULARLY FOR LUBRICATING SHEET METAL DURING ROLLING Filed D80. 7, 1954 2 Sheetssheet 1 COMPRESSED A? M157- I t STE/1M A, ATTORNEVj Jan. 22, 1957 e. E. TURPIN 2,778,616
MEANS FOR ATOMIZING LIQUIDS, PARTICULARLY FOR LUBRICATING SHEET METAL DURING ROLLING Filed D90. 7, 1954 2 Sheets-Sheet 2 INVENTOR Adam @W, )w eI I, ATTORNEYS United States Patent Geoffrey Edgar Turpin, Sketty, Swansea, Wales, assignor to The Steel Company of Wales Limited, Port Talbot, Wales Application December 7, 1954, Serial N 0. 473,713
Claims priority, application Great Britain January 28, 1954 2 Claims. (Cl. 261-14) This invention relates to means for atomising liquids, particularly for lubricating sheet metal during rolling.
In my patent specification No. 2,707,098, datedApril 26, 1955, an atomising device is described comprising a hollow-walled tubular barrel, a casing disposed outside said tubular barrel forming an outer conduit surrounding said barrel, a compressed air inlet connection at one end of said outer conduit, transfer connection means at the other end of said outer conduit leading into the adjacent end of the bore of the tubular barrel, an injection device for delivering liquid into said bore longitudinally at a position adjacent the transfer connection means, so that heated 'air from the outer conduit is charged with liquid globules and then flows back along the bore of the tubular barrel to that end thereof adjacent the said one end of the outer conduit, and delivery means for the heated spray-laden air at that end of the bore, the hollow Wall of the tubular barrel being provided with inlet and outlet connections for heating fluid. the invention to provide an improvement in or modification of this form of device, whereby better atomisation of the liquid is achieved. The improved device, moreover, is capable of operating satisfactorily under higher delivery pressures than the previous construction.
In an atomising device comprising a hollow-walled tubular barrel through the wall of which a heating fluid is passed, a casing disposed outside said tubular barrel forming an outer conduit surrounding said barrel, a compressed air inlet connection at one end of said outer conduit, transfer connection means at the other end of said outer conduit leading into the adjacent end of the bore of the tubular barrel, an injection device for delivering liquid into said bore longitudinally at a position adjacent the transfer connection means, so that heated air from the outer conduit is charged with liquid globules as it flows back along the bore of the tubular barrel to a mixture outlet at the far end of said bore, the invention is characterised by the fact that injection and mixing means within the bore of the tubular barrel comprise a liquid injection nozzle directed along said bore-and a plurality of air nozzles fed with heated air from the outer conduit and arranged to discharge said air at positions posterior to the liquid nozzle.
Preferably the delivery orifices of the air nozzles are disposed at a plurality of positions along the bore of the tubular barrel. The air nozzles may comprise tubular stems mounted in a partition extending across the bore of the tubular barrel. Thus the air nozzles can all extend parallel with the axis of the tubular barrel and are arranged as a circular array disposed around the liquid injection nozzle. Advantageously the air nozzles comprise tubes having their end portions partially flattened to form slot-like delivery orifices, these preferably being arranged radially. The liquid injection nozzle may comprise a jet tube having an axial duct along which the liquid flows, an axially adjustable needle valve member being arranged It is an object of ICC to cooperate with an annular shoulder in said duct to regulate the flow of liquid therealong; the needle valve member may be fitted into the jet tube, said jet tube and valve member being removable as a unit from the tubular barrel.
The invention is illustrated in the accompanying drawings, in which:
Figure l. is a diagram in the form of a longitudinal section to show the general arrangement of the improved atomising device and the various fluid spaces and passages therein;
Figure 2 is a transverse sectional elevation of a practical embodiment, the section being taken to correspond with the line 2-2 of Figure l and being drawn to an enlarged scale; and
Figure 3 is a fragmentary longitudinal sectional elevation taken on the line 33 of Figure 2, and showing the air and liquid nozzles.
The atomising device shown in Figure 1 is used primarily for spraying palm oil on to sheet metal while it is being rolled. Palm oil is solid at ordinary temperatures but it can be melted and by using the appropriate form of atomiser it can be converted to a fine mist which is suitable for spraying on the sheet metal so as to produce a very thin uniform coating of palm oil thereon prior to rolling.
The device comprises a straight inner tube 10 which is surrounded by an intermediate tube 11, the two being connected at their ends so as to form a hollow-walled barrel, the annular chamber thereof being indicated at 12. The chamber forms a heating jacket which is fed with steam through an inlet 13, said steam passing along the chamber 12 from left to right and being exhausted through a steam outlet 14. An outer casing 15 is fitted around the tubular barrel 1%, 11 and is also closed at its ends to form an outer conduit 16 which is of annular shape in cross section. At its left-hand end it has an inlet 17 for compressed air, While at its right-hand end it leads into a number of radial passages forming transfer means, two of these passages being shown at 18 in Figure 1. They lead into a compartment 19 forming the right-hand end of the bore 2% of the inner tube 10, said compartment 19 being bounded by a partition 21. This partition 21 supports four air nozzles in the form of small diameter tubes which extend longitudinally of the bore 20, only two of said tubes being shown at 22. These tubes are fed with air from' the compartment 19 and as they are of different lengths they serve to deliver said air at different positions along the bore of the inner tube 10.
The liquid inlet is shown at 24 and leads into a chamber 25 from which a jet tube 26 extends axially through the compartment 19 and partition 21, said jet tube terminating just beyond said partition. An adjustable needle valve 27 is provided in connection with the chamber 25 so as to enable the flow of liquid to be regulated closely to suit requirements. At its left-hand end the inner tube 10 leads to a delivery outlet28 which is conveniently in the form of an elbow or other pipe.
In operation therefore the steam which is circulated continuously through the chamber 12 causes the tubes 10 and 11 to be maintained in a heated state. The compressed air as it travels along the outer conduit 16 becomes heated so that as it issues from the air nozzle 22'it readily breaks up the liquid spray which is being injected into the bore 20 from the jet tube 26. As will be hereinafter described, the air nozzles are so constructed as to produce considerable turbulence within the bore 20 so that the mixture becomes further heated as it flows along the internal wall of the tube It), so that the product which is delivered through the outlet 28 is in a finely mixed anduniform state.
Details of the preferred practical embodiment are shown in Figures 2 and 3, the main parts being indicated by the same reference numerals as are used in Figure 1. The partition 21 is fitted into the end of the tube and is formed with a tubular extension 29, which is in turn secured within a bore formed in a body 31, the bore 38 constituting the compartment 19. At its left-hand end the body 31 is enlarged in diameter and is formed with two shoulders 32 and 33 which serve for locating the ends of the intermediate tube 11 and the outer casing 15. It also has a number of longitudinal passages 34 which communicate with the annular chamber 12 inside the intermediate tube 11 and connects said chamber to the interior of an annular cap 35 having the steam outlet 1 formed on its lower part. The radial passages 18 are drilled at positions intermediate the longitudinal passages 34 and thus form the interconnecting means between the outer conduit 16 and the compartment 19.
The body 31 has an axial bore 36 into which a liquid jet tube 37 fits snugly, said tube having its forward end extending axially through the compartment 19 and through a hole 38 formed centrally in the partition 21, its delivery orifice 39 being substantially flush with the left-hand face of said'partition. The jet tube 37 is enlarged in diameter at its right-hand end and is formed with a screwthread 48 by which it is secured in the body 31. The jet tube 37 has an axial duct 41 terminating in an annular shoulder 42, which cooperates with the tapered end 43 of a needle valve member 44, the latter having a stem portion 45 which is screw-threaded into the jet tube and is provided with an adjusting knob 46; a lock-nut 47 serves to hold the desired adjustment. Adjacent the screw-threaded portion 40, the jet tube 37 has a number of radial passageways 48 which communicate with an annular groove 49 in the body 39 and thus serve for feeding liquid from the liquid inlet 24 past the shoulder 42 to the axial duct 41 and delivery orifice 39.
The air jet tubes 22 are set into the partition 21 and are of different lengths so that the air from the compartment 19 is delivered at high velocity to diiferent points along the length of the bore 20. Thus if the bore 28 is about 20 inches long, the four tubes 22 can advantageously be about 2, 4, 6 and 8 inches long respectively As shown in Figure 2, each has its end partially flattened to form a slot-shaped delivery jet orifice 5d, the slots being arranged radially as seen in end view. Also the ends of the tubes are preferably cut off obliquely as indicated at 50:: in Figure 3.
The unit is conveniently provided with a socket 51 into which a pressure gauge 52 (Figure 1) can be fitted to show the air pressure which is being fed to the air jet tubes 22.
It should be mentioned that most of the parts of the atomising device described are Welded together to form a robust, fluid-tight unit, and that the actual design of the various components can be modified to suit manufacturing requirements. Moreover it will be understood that the details which have been described are given by way of example only, and that various modifications may be made to suit requirements.
I claim:
1. An apparatus for producing a spray of atomised liquid, such as heated palm oil, comprising an inner tube, an oil injection nozzle disposed within one end of said inner tube, spray delivery means at the other end of said inner tube, an intermediate tube surrounding the inner tube but spaced therefrom to form an intermediate annular heating jacket, means for passing heating fluid along said heating jacket, an outer tube surrounding the intermediate tube but spaced therefrom to form an outer annular chamber which is of small radial thickness and is shorter in axial length than the heating jacket, said outer annular chamber being carried wholly upon the outside of the intermediate tube, means for feeding compressed air into the outer annular chamber at that end thereof adjacent the delivery end of the inner tube, transfer conduit means forming a connection for compressed air extending inwards from the outer annular chamber, a multiple nozzle device which is disposed in the bore of the inner tube adjacent the inlet end thereof, and which comprises a wall closing the bore of said tube, a plurality of air nozzle tubes mounted in the wall and directed towards the delivery end of said inner tube, the delivery ends of said air nozzle tubes being flattened to form narrow par allel-sided delivery nozzles, said nozzles being arranged in a circular series around the axis of the inner tube and having their parallel sides disposed substantially radially with respect to said axis, said air nozzle tubes being fed with heated air from the transfer conduit means, and fins anchored to the outside of the intermediate tube and extending outwards within the outer annular chamber to increase the transmission of heat to the compressed air before it reaches the transfer conduit means.
2. An apparatus for producing a spray of atomised liquid, such as heated palm oil, comprising an inner tube, an oil injection nozzle disposed within one end of said inner tube, spray delivery means at the other end of said inner tube, an intermediate tube surrounding the inner tube but spaced therefrom to form an intermediate annular heating jacket, means for passing heating fluid along said heating jacket, an outer tube surrounding the intermediatetube but spaced therefrom to form an outer annular chamber, which is of small radial thickness and is shorter in axial length than the heating jacket, said outer annular chamber being carried wholly upon the outside of the intermediate tube, means for feeding compressed air into the outer annular chamber at that end thereof adjacent the delivery end of the inner tube, transfer conduit means forming a connection for compressed air extending inwards from the outer annular chamber, a multiple nozzle device which is disposed in the bore of the inner tube adjacent the inlet end thereof, and which comprises a wall closing the bore of said tube, a plurality of air nozzle tubes mounted in the wall and directed towards the delivery end of said inner tube, said air nozzle tubes being of difierent lengths and having their delivery ends disposed at positions spaced along the length of the inner tube and being fed'with heated air from the transfer conduit means and delivering it at spaced points along the length of the inner tube, and fins anchored to the outside of the intermediate tube and extending outwards within the outer annular chamber to increase the transmission of heat to the compressed air before it reaches the transfer conduit means.
References Cited in the file of this patent UNITED STATES YATENTS 1,339,709 Mohn May 11, 1920 2,086,183 Gellner et a1. July 6, 1937 2,303,648 Lemster et al Dec. 1, 1942 2,332,210 Frank Oct. 19, 1943 2,478,557 Bell et a1. Aug. 9, 1949 2,707,098 Turpin Apr. 26, 1955

Claims (1)

  1. 2. AN APPARATUS FOR PRODUCING A SPRAY OF ATOMISED LIQUID, SUCH AS HEATED PALM OIL, COMPRISING AN INNER TUBE, AN OIL INJECTION NOZZLE DISPOSED WITHIN ONE END OF SAID INNER TUBE, SPRAY DELIVERY MEANS AT THE OTHER END OF SAID INNER TUBE, AN INTERMEDIATE TUBE SURROUNDING THE INNER TUBE BUT SPACED THEREFROM TO FORM AN INTERMEDIATE ANNULAR HEATING JACKET, MEANS FOR PASSING HEATING FLUID ALONG SAID HEATING JACKET, AN OUTER TUBE SURROUNDING THE INTERMEDIATE TUBE BUT SPACED THEREFROM TO FORM AN OUTER ANNULAR CHAMBER, WHICH IS OF SMALL RADIAL THICKNESS AND IS SHORTER IN AXIAL LENGTH THAN THE HEATING JACKET, SAID OUTER ANNULAR CHAMBER BEING CARRIED WHOLLY UPON THE OUTSIDE OF THE INTERMEDIATE TUBE, MEANS FOR FEEDING COMPRESSED AIR INTO THE OUTER ANNULAR CHAMBER AT THAT END THEREOF ADJACENT THE DELIVERY END OF THE INNER TUBE, TRANSFER CONDUIT MEANS FORMING A CONNECTION FOR COMPRESSED AIR EXTENDING INWARDS FROM THE OUTER ANNULAR CHAMBER, A MULTIPLE NOZZLE DEVICE WHICH IS DISPOSED IN THE BORE OF THE INNER TUBE ADJACENT THE INLET END THEREOF, AND WHICH COMPRISE A WALL CLOSING THE BORE OF SAID TUBE, A PLURALITY OF AIR NOZZLE TUBES MOUNTED IN THE WALL AND DIRECTED TOWARDS THE DELIVERY END OF SAID INNER TUBE, SAID AIR NOZZLE TUBES BEING OF DIFFERENT LENGTHS AND HAVING THEIR DELIVERY ENDS DISPOSED AT POSITIONS SPACED ALONG THE LENGTH OF THE INNER TUBE AND BEING FED WITH HEATED AIR FROM THE TRANSFER CONDUIT MEANS AND DELIVERING IT AT SPACED POINTS ALONG THE LENGTH OF THE INNER TUBE, AND FINS ANCHORED TO THE OUTSED OF THE INTERMEDIATE TUBE AND EXTENDING OUTWARDS WITHIN THE OUTER ANNULAR CHAMBER TO INCREASE THE TRANSMISSION OF HEAT TO THE COMPRESSED AIR BEFORE IT REACHES THE TRANSFER CONDUIT MEANS.
US473713A 1954-01-28 1954-12-07 Means for atomizing liquids, particularly for lubricating sheet metal during rolling Expired - Lifetime US2778616A (en)

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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3523437A (en) * 1967-12-07 1970-08-11 United States Steel Corp Method of cold reducing
US3765189A (en) * 1972-02-17 1973-10-16 Air Liquide Method and apparatus for deep-freezing
US3823872A (en) * 1971-11-19 1974-07-16 Snecma Nozzle for use in hot liquid ejector pumps, and related process
US20050198809A1 (en) * 2004-03-10 2005-09-15 Takashi Fujii Working system of metallic wire rod

Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1339709A (en) * 1919-12-04 1920-05-11 Augustus A Mohn Liquid-hydrocarbon burner of the injection type
US2086183A (en) * 1934-02-23 1937-07-06 Gellner Ludwig Apparatus for spraying of colors and the like
US2303648A (en) * 1941-10-02 1942-12-01 Devon E Lemster Burner
US2332210A (en) * 1943-10-19 Ignition apparatus
US2478557A (en) * 1947-09-13 1949-08-09 Walter H Bell Sprayer and sprayer head for fluent coating materials
US2707098A (en) * 1951-11-27 1955-04-26 Steel Company Means for lubricating sheet metal during rolling

Patent Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2332210A (en) * 1943-10-19 Ignition apparatus
US1339709A (en) * 1919-12-04 1920-05-11 Augustus A Mohn Liquid-hydrocarbon burner of the injection type
US2086183A (en) * 1934-02-23 1937-07-06 Gellner Ludwig Apparatus for spraying of colors and the like
US2303648A (en) * 1941-10-02 1942-12-01 Devon E Lemster Burner
US2478557A (en) * 1947-09-13 1949-08-09 Walter H Bell Sprayer and sprayer head for fluent coating materials
US2707098A (en) * 1951-11-27 1955-04-26 Steel Company Means for lubricating sheet metal during rolling

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3523437A (en) * 1967-12-07 1970-08-11 United States Steel Corp Method of cold reducing
US3823872A (en) * 1971-11-19 1974-07-16 Snecma Nozzle for use in hot liquid ejector pumps, and related process
US3765189A (en) * 1972-02-17 1973-10-16 Air Liquide Method and apparatus for deep-freezing
US20050198809A1 (en) * 2004-03-10 2005-09-15 Takashi Fujii Working system of metallic wire rod

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