US1536176A - Method of preventing the crusty formation of solidified oxides - Google Patents

Method of preventing the crusty formation of solidified oxides Download PDF

Info

Publication number
US1536176A
US1536176A US520000A US52000021A US1536176A US 1536176 A US1536176 A US 1536176A US 520000 A US520000 A US 520000A US 52000021 A US52000021 A US 52000021A US 1536176 A US1536176 A US 1536176A
Authority
US
United States
Prior art keywords
formation
crusty
preventing
mouth
oxides
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US520000A
Inventor
Charles H Aldrich
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
PAUL J KRUESI
Original Assignee
PAUL J KRUESI
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by PAUL J KRUESI filed Critical PAUL J KRUESI
Priority to US520000A priority Critical patent/US1536176A/en
Application granted granted Critical
Publication of US1536176A publication Critical patent/US1536176A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • CCHEMISTRY; METALLURGY
    • C01INORGANIC CHEMISTRY
    • C01GCOMPOUNDS CONTAINING METALS NOT COVERED BY SUBCLASSES C01D OR C01F
    • C01G9/00Compounds of zinc
    • C01G9/02Oxides; Hydroxides

Definitions

  • TRUSTEE 0F CHATTANOOGA, TENNESSEE.
  • My invention relates in general to methods of forming solid oxides and in particular to such methods in which volatile metals, such as, zinc, cadmium, or the like are volatilized and then burned.
  • any su1tab1e apparatus by means of which a sufiicient amount of a reducing or inert gas may be introduced into and around the vapor as it is issuing from the mouth of the retort or furnace. Combustion is thereby retarded so that it does not start at once, but usually at a oint a number of inches away from theego of the orifice through which the vapors emerge.
  • the point of initial combustion is regulated by the amount of reducing gas used. Under these conditions, no crusty material is formed and there is a complete conversion of the volatile metal into a uniformly good oxide.
  • Fig. 1 is a side elevation of the complete device, partly in section.
  • Fig. 2 is an enlarged, sectional elevation of the gas burner...
  • Fig. 3 is a plan view of the same.
  • Fig. 4 is a view of the burner, slightl enlarged, and shows the point at whic combustion of the metal vapors takes place.
  • 5 represents a retort or furnace of any type suitable for bringing the volatile metals to their boiling points.
  • I have shown in a fragmentary manner a settling or precipitating chamber in which the oxides may settle.
  • a burner 7 Arranged on top of the retort 5, and preferably at an angle of 45, is a burner 7.
  • hood 8 is provided over the, burner and incloses an opening 9 formed through the wall of the settling chamber.
  • the hood 8 is provided with a bottom 10 which is-arranged at a suitable distance away from the top surface of the burner 7 and in which an opening 11 is formed. The opening 11 is in registering position with the mouth of the burner.
  • the burner 7 comprises a cone 15, which is formed of refractory material and provided with a central opening 16, which is arranged to register wlth the opening (not shown) of the retort.
  • the line 17 represents the upper surface of the retort.
  • a metallic casing 18 Surrounding the cone 15 is a metallic casing 18, which is formed by an outer wall 19, an inner wall 20, a bottom wall 21, and a top wall 22.
  • An annular gas space 23, is provided by these walls, and a pipe 24 is connected to the ring 18 whereby some suitable reducing or inert gas may be conducted to the s ace in the ring.
  • the top wall 22 is provided with a central opening 25, which is slightly larger in diameter than the portion of the cone 16 which it surrounds, whereby an opening 26 is provided.
  • the inner wall 20 is-inclined inwardly at substantially the same angle as the outer surface of the cone 15, and a space 27 is provided between this wall and the outer surfaceof the cone.
  • the upper edge of the inner wall 20 is arranged some distance from the inner surface of the top wall 22, whereby an annular space 28 is provided.
  • the gas coming from the pipe 24; will pass through this space 28, and will be projected outwardl through the space 26. So as to equally" istribute the flow of gas from the plpe 24 a bafie plate 29 is arranged in front of the pipe.
  • the ring 18 is provided with a plurality of legs 30, with spaces 31 arranged between them. This provides a space below the ring in which sediment and dirt may accumulate.
  • a band 82 is arranged about the ring 18, for closing the spaces 81, except when the burner is being cleaned.
  • the inert or reducin gas coming from the pipe 24 will be force l out throu h the openings 28 and 26 and will not immediately mix with a stream of metallic vapor as it is issuing from the central opening 16 in the cone 15 until the stream 0 vapor is some distance i from the mouth of the cone.
  • the angle of the outer periphery of the cone 15 is such that the gas will be projected inwardly toward the vapor and will cause combustion to occur at some distance away from the mouth of the burner. is clearly shown in Fig. 1-, where it will be seen that there is a space 35 between the mouth of the burner and the flame of metal vapor which is represented at 36.
  • the flame does not touch any part of the burner and therefore there will be no formation of oxide at the mouth of the burner. Neither will there be any condensation of the vapors due tothe formation of oxide around the mouth of the burner.
  • the bottom 10 of the hood 8 is so arranged in relation to the top of the burner th at the flame 36 occurs'within or slightly beyond the opening 11 in the bottom.
  • the vapors, issuing from the burner and the inert gas which protects the same, are not mixed or commingled since the volume of inert gas necessary to prevent oxidization is preferably very much less than the volume of vapor jet, and since the velocity of the gases are relatively high.
  • a method of preventing the crusty formation of solidified oxides at or in the delivery mouth of a volatilizing retort which consists in surrounding the issuing jet of metallic vapor with a relatively thin envelop of flowing inert gas.
  • a method of preventing the crusty formation of solidified oxides which comprises thevolatilization of metal in a suitable furnace and then surrounding the metallic vapor, at its place of issue from the furnace, with a tubular envelop of flowing inert gas.
  • a method of preventing the crusty formation of solidified oxides at the mouth of a volatilizing furnace which consists in surrounding the flowing metallic vapor with a flowing tubular envelop of inert gas, the gas being such and so disposed that the desired oxidizing reaction does not take place except at some distance from the mouth of the furnace.
  • a method of preventing the crusty formation of solidified oxides at the mouth of a volatilizing furnace which consists imcausing the vapor to ass through a tubular envelop of impelled inert gas, whereby oxidization at the mouth of the furnace is prevented.
  • a method of preventing the crusty formation of solidified oxides comprising the volatilization of the metal in a suitable furnace, and then enveloping the vapors, as they issue from the furnace, with a gas, whereby 1,:sse,17e B combustion occurs at some distance from the mouth of the furnace.
  • a method of preventing the crusty for- I motion of solidified oxides at the mouth of 1% the vola- 5 a. volatilizing furnace compris tilization of the metal in a suite e furnace, then enveloping the .va are as they issue from the mouth of the ace with an inert or reducing gas for preventing combustion of such vapors and gases until the val0 pors have reached a point some distance from the mouth of the furnace.

Description

' May 5, 1925.
C. H. ALDRICH METHOD OF PREYEN'LINCT THE CRUSTY FORMATION OF SOLIDIFIED OXIDES Filed Dec jg ull Ewan ATTORNEY Patented May 5, 1925.
UNITED STATES CHARLES H. ALDRICH, OF KEEINE, NEW HAMPSHIRE. ASSIGNOB TO PAUL, J. KBUESI,
TRUSTEE, 0F CHATTANOOGA, TENNESSEE.
IETHOD 0F PREVENTING THE ORUSTY FORMATION 0F SbLIDIFIED OXIDES.
Application filed December 5, 1921.
To all whom it may concern:
Be it'known that 1, CHARLES H. Anmuon, a citizen of the United States of America, and a resident of the city of Keene, county of Cheshire, and State of New Hampshire, have invented certain new anduseful Imrovements in Methods of Preventing the rusty Formation of Solidified Oxides, of which the following is a full, clear, and exact description.
My invention relates in general to methods of forming solid oxides and in particular to such methods in which volatile metals, such as, zinc, cadmium, or the like are volatilized and then burned.
For convenience in this specification, I will describe the formation of zinc oxides from the burning of zinc vapor, it being obvious that the method. of producing solid oxides from other metals will be substantially the same.
It is well known to those skilled in the art that in the manufacture of zinc oxide, the metallic zinc or spelter is charged into retorts, after which the metal is heated by any suitable means to the boiling point, and the zinc vapor issuing from the mouth of the retort is burned under a suitable hood, the fumes of zinc oxide, together with a large excess of air, being drawn through cooling flues and caught in a suitable collecting system, usually settling or precipitating chambers, or a bag house, or both. In present 'day practice, it is customary to par. tially close the mouth of the retort to diminlsh the admission of air, thereby correspondingly increasing the formation. of oxide within the retort.
Under these conditions there is a rapid formation or building up of a hard deposit of crusty zinc oxide surrounding the issuing stream of zinc vapor, at the point where the zinc vapor comes in contact with the air. This deposit builds up very rapidly; and; if left alone, it would soon become large enou h to block the hood, surrounding the mout of the retort, and even close the retort itself; As this deposit of zinc usually assumes a tubular form, it acts as a condenser, with the result that condensed zinc forms on the inner surface of the tube and runs back into the retort or leaks out in the metallic state.
Sincethis crusty material is of no commercial value as zinc oxide but must be Serial No. 520,000.
point Where air comes in contact with the stream of issuing vapor. Moreover, I have discovered by means of these experiments, that 1f, by any means, the combustion of the vapor can be retarded so that the zone of combustion is some distance away from the edge of the nozzle, there will be no formation of crust, and all of the vapor will be converted into marketable'oxide.
In carrying out my invention, I have discovered that this may be accomplished b any su1tab1e apparatus by means of which a sufiicient amount of a reducing or inert gas may be introduced into and around the vapor as it is issuing from the mouth of the retort or furnace. Combustion is thereby retarded so that it does not start at once, but usually at a oint a number of inches away from theego of the orifice through which the vapors emerge. The point of initial combustion is regulated by the amount of reducing gas used. Under these conditions, no crusty material is formed and there is a complete conversion of the volatile metal into a uniformly good oxide. In the accompanying drawings, I haveshown one form of apparatus for carrying out my invention, it being obvious that other forms of devices may be used in accomplishing the desired results. In the drawings:
Fig. 1 is a side elevation of the complete device, partly in section.
Fig. 2 is an enlarged, sectional elevation of the gas burner...
Fig. 3 is a plan view of the same.
Fig. 4 is a view of the burner, slightl enlarged, and shows the point at whic combustion of the metal vapors takes place.
In the drawings, 5 represents a retort or furnace of any type suitable for bringing the volatile metals to their boiling points. At 6, I have shown in a fragmentary manner a settling or precipitating chamber in which the oxides may settle.
Arranged on top of the retort 5, and preferably at an angle of 45, is a burner 7. hood 8 is provided over the, burner and incloses an opening 9 formed through the wall of the settling chamber. The hood 8 is provided with a bottom 10 which is-arranged at a suitable distance away from the top surface of the burner 7 and in which an opening 11 is formed. The opening 11 is in registering position with the mouth of the burner.
, Referring now more particularly to Figs. 2 and 3, it will be seen that the burner 7 comprises a cone 15, which is formed of refractory material and provided with a central opening 16, which is arranged to register wlth the opening (not shown) of the retort. In Fig. 2 the line 17 represents the upper surface of the retort. Surrounding the cone 15 is a metallic casing 18, which is formed by an outer wall 19, an inner wall 20, a bottom wall 21, and a top wall 22. An annular gas space 23, is provided by these walls, and a pipe 24 is connected to the ring 18 whereby some suitable reducing or inert gas may be conducted to the s ace in the ring. The top wall 22 is provided with a central opening 25, which is slightly larger in diameter than the portion of the cone 16 which it surrounds, whereby an opening 26 is provided. The inner wall 20 is-inclined inwardly at substantially the same angle as the outer surface of the cone 15, and a space 27 is provided between this wall and the outer surfaceof the cone. The upper edge of the inner wall 20 is arranged some distance from the inner surface of the top wall 22, whereby an annular space 28 is provided. The gas coming from the pipe 24; will pass through this space 28, and will be projected outwardl through the space 26. So as to equally" istribute the flow of gas from the plpe 24 a bafie plate 29 is arranged in front of the pipe.
The ring 18 is provided with a plurality of legs 30, with spaces 31 arranged between them. This provides a space below the ring in which sediment and dirt may accumulate. A band 82is arranged about the ring 18, for closing the spaces 81, except when the burner is being cleaned.
When the apparatus is in operation the inert or reducin gas coming from the pipe 24 will be force l out throu h the openings 28 and 26 and will not immediately mix with a stream of metallic vapor as it is issuing from the central opening 16 in the cone 15 until the stream 0 vapor is some distance i from the mouth of the cone. The angle of the outer periphery of the cone 15 is such that the gas will be projected inwardly toward the vapor and will cause combustion to occur at some distance away from the mouth of the burner. is clearly shown in Fig. 1-, where it will be seen that there is a space 35 between the mouth of the burner and the flame of metal vapor which is represented at 36. As shown in this figure, the flame does not touch any part of the burner and therefore there will be no formation of oxide at the mouth of the burner. Neither will there be any condensation of the vapors due tothe formation of oxide around the mouth of the burner. The bottom 10 of the hood 8 is so arranged in relation to the top of the burner th at the flame 36 occurs'within or slightly beyond the opening 11 in the bottom.
The vapors, issuing from the burner and the inert gas which protects the same, are not mixed or commingled since the volume of inert gas necessary to prevent oxidization is preferably very much less than the volume of vapor jet, and since the velocity of the gases are relatively high.
Having thus described my invention, what I claim is:
1. A method of preventing the crusty formation of solidified oxides at or in the delivery mouth of a volatilizing retort, which consists in surrounding the issuing jet of metallic vapor with a relatively thin envelop of flowing inert gas.
2. A method of preventing the crusty formation of solidified oxides, which comprises thevolatilization of metal in a suitable furnace and then surrounding the metallic vapor, at its place of issue from the furnace, with a tubular envelop of flowing inert gas.
3. A method of preventing the crusty formation of solidified oxides at the mouth of a volatilizing furnace, which consists in surrounding the flowing metallic vapor with a flowing tubular envelop of inert gas, the gas being such and so disposed that the desired oxidizing reaction does not take place except at some distance from the mouth of the furnace.
4:. A method of preventing the crusty formation of solidified oxides at the mouth of a volatilizing furnace which consists imcausing the vapor to ass through a tubular envelop of impelled inert gas, whereby oxidization at the mouth of the furnace is prevented.
5. A method of temporaril preventing the contact "of oxygen with a owing jet of volatilized metal 1n its traverse of a gap between the mouth of a volatilizing furnace and an oxidizing chamber, which consists in I interposing a barrier of flowing inert oxygenexcluding gas between the atmosphenc air and the gas.
6. A method of preventing the crusty formation of solidified oxides comprising the volatilization of the metal in a suitable furnace, and then enveloping the vapors, as they issue from the furnace, with a gas, whereby 1,:sse,17e B combustion occurs at some distance from the mouth of the furnace.
7. A method of preventing the crusty for- I motion of solidified oxides at the mouth of 1% the vola- 5 a. volatilizing furnace compris tilization of the metal in a suite e furnace, then enveloping the .va are as they issue from the mouth of the ace with an inert or reducing gas for preventing combustion of such vapors and gases until the val0 pors have reached a point some distance from the mouth of the furnace.
In testimony whereof, I have hereunto signed my name.
CHARLES H. ALDRICH.
US520000A 1921-12-05 1921-12-05 Method of preventing the crusty formation of solidified oxides Expired - Lifetime US1536176A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US520000A US1536176A (en) 1921-12-05 1921-12-05 Method of preventing the crusty formation of solidified oxides

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US520000A US1536176A (en) 1921-12-05 1921-12-05 Method of preventing the crusty formation of solidified oxides

Publications (1)

Publication Number Publication Date
US1536176A true US1536176A (en) 1925-05-05

Family

ID=24070765

Family Applications (1)

Application Number Title Priority Date Filing Date
US520000A Expired - Lifetime US1536176A (en) 1921-12-05 1921-12-05 Method of preventing the crusty formation of solidified oxides

Country Status (1)

Country Link
US (1) US1536176A (en)

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2618325A (en) * 1948-05-28 1952-11-18 Air Reduction Method of controlling a burner flame
US2782118A (en) * 1952-02-19 1957-02-19 Monsanto Chemicals Production of refractory metals
US2805151A (en) * 1953-09-29 1957-09-03 Du Pont Method of minimizing product buildup in the production of metal including titanium and zirconium
US2816828A (en) * 1956-06-20 1957-12-17 Nat Res Corp Method of producing refractory metals
US2870007A (en) * 1952-07-17 1959-01-20 Degussa Process for the production of metals by reduction of their compounds in the vapor phase
US3006738A (en) * 1957-10-10 1961-10-31 Degussa Burner for production of finely divided oxides
US3085865A (en) * 1961-02-17 1963-04-16 Union Carbide Corp Apparatus for the oxidation of metal powders
US3086851A (en) * 1957-10-10 1963-04-23 Degussa Burner for production of finely divided oxides
US3592391A (en) * 1969-01-27 1971-07-13 Knapsack Ag Nozzle for atomizing molten material
US4048797A (en) * 1974-12-06 1977-09-20 The Secretary Of State For Defence In Her Britannic Majesty's Government Of The United Kingdom Of Great Britain And Northern Ireland Combustion apparatus

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2618325A (en) * 1948-05-28 1952-11-18 Air Reduction Method of controlling a burner flame
US2782118A (en) * 1952-02-19 1957-02-19 Monsanto Chemicals Production of refractory metals
US2870007A (en) * 1952-07-17 1959-01-20 Degussa Process for the production of metals by reduction of their compounds in the vapor phase
US2805151A (en) * 1953-09-29 1957-09-03 Du Pont Method of minimizing product buildup in the production of metal including titanium and zirconium
US2816828A (en) * 1956-06-20 1957-12-17 Nat Res Corp Method of producing refractory metals
US3006738A (en) * 1957-10-10 1961-10-31 Degussa Burner for production of finely divided oxides
US3086851A (en) * 1957-10-10 1963-04-23 Degussa Burner for production of finely divided oxides
US3085865A (en) * 1961-02-17 1963-04-16 Union Carbide Corp Apparatus for the oxidation of metal powders
US3592391A (en) * 1969-01-27 1971-07-13 Knapsack Ag Nozzle for atomizing molten material
US4048797A (en) * 1974-12-06 1977-09-20 The Secretary Of State For Defence In Her Britannic Majesty's Government Of The United Kingdom Of Great Britain And Northern Ireland Combustion apparatus

Similar Documents

Publication Publication Date Title
US1536176A (en) Method of preventing the crusty formation of solidified oxides
US1363188A (en) Method of and furnace for melting metallic masses
US1202953A (en) Spark-arrester.
US1977117A (en) Process for the separate recovery of volatile metals, nonmetals, or volatile or gaseous metallic or nonmetallic compounds
US1147644A (en) Carbureting device.
US1940125A (en) Manufacture of zinc oxide
US2705189A (en) Carbon black
US2492438A (en) Process for vertical retort smelting of zinciferous materials
US3357794A (en) Process and apparatus for continuously producing titanium dioxide by the oxidation of vaporized titanium tetrachloride
US111288A (en) Atid blast heating
US1082530A (en) Apparatus for manufacturing mercury bichlorid.
US2007332A (en) Apparatus for the distillation of zinc and other volatile metals
US1698367A (en) Pit furnace
US2380548A (en) Zinc condenser
US2019536A (en) Process and apparatus for producing finely divided lead and lead compounds
US1685229A (en) Apparatus for treating fumes
US2065617A (en) Method for the recovery of sulphuric acid
US695376A (en) Production of zinc-dust.
US1681496A (en) Process for refining crude arsenic trioxide
GB225833A (en) Improved manufacture of zinc-oxide
DE485835C (en) Rotary kiln and smelting furnace for the direct production of cast iron or steel from iron ores
SU509540A1 (en) Installation for producing oxides of cadmium
US1503564A (en) Electric furnace and precipitator for producing oxide of zinc
US454856A (en) Beockhobp
US1966627A (en) Distillation apparatus for the production of zinc or similar volatilizable metals