US2762707A - Process of producing flints by means of extrusion - Google Patents

Process of producing flints by means of extrusion Download PDF

Info

Publication number
US2762707A
US2762707A US381738A US38173853A US2762707A US 2762707 A US2762707 A US 2762707A US 381738 A US381738 A US 381738A US 38173853 A US38173853 A US 38173853A US 2762707 A US2762707 A US 2762707A
Authority
US
United States
Prior art keywords
cerium
iron
alloy
extrusion
ingot
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
US381738A
Inventor
Bungardt Walter
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.)
Evonik Operations GmbH
Original Assignee
TH Goldschmidt AG
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 TH Goldschmidt AG filed Critical TH Goldschmidt AG
Application granted granted Critical
Publication of US2762707A publication Critical patent/US2762707A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Classifications

    • CCHEMISTRY; METALLURGY
    • C06EXPLOSIVES; MATCHES
    • C06CDETONATING OR PRIMING DEVICES; FUSES; CHEMICAL LIGHTERS; PYROPHORIC COMPOSITIONS
    • C06C15/00Pyrophoric compositions; Flints

Definitions

  • Cerium-iron alloy flints are usually made by casting. It has been proposed to make flints of this kind by the extrusion process which is more economical than casting. The known attempts inthisv direction have failed. It was found that the pyrophoric properties of the alloy were lost during the extrusion process, hence the process has been described intechnical literature as completely useless.
  • the present invention proceeds from the recognition that the diminution of pyrophoric properties during extrusion is to be attributed to the fact that, on extrusion, the cerium-iron crystals, to which the pyrophoric action of the cerium-iron alloys is to be ascribed, are shattered and that consequently a larger quantity of eutectic matrix is necessary in order to embed sufliciently the fragments of the cerium-iron crystals so that they are protected against breaking out when subjected to friction by the friction Wheel of a lighter.
  • Researches have shown that the necessary quantity of eutectic matrix increases with the increase in size of the cerium iron crystals in the ingot introduced into the extrusion press.
  • the eutectic matrix has not only the task of embedding the cerium-iron crystals and protecting them from breaking away, but also of increasing the pyrophoric properties of the cerium-iron crystals.
  • the eutectic matrix is readily oxidizable, but oxidation manifests itself not in spark formation on friction but only in heat production; however this heat production favors the flaming of the pyrophoric crystal fragments.
  • the best cerium-iron alloy for flints produced by casting consists of about 30 to 40% iron, the remainder being cerium. The amount of eutectic matrix increases with the decrease in the iron content.
  • the iron content may be lowered to to 25% of the total alloy-age. It was found that with ingots with an iron content lowered to from 15 to 25%, when they are produced in a normal manner, such a quantity of eutectic groundmass or matrix of the invention to providemeans.
  • the crystals shouldnot be below a minimum size, otherwise they lose their pyrophoric properties. It has now been found, however, that by the use of inoculant' additions, i. e. additions resulting from the production of more numerous but smaller crystals, or by accelerated cooling of the ingot, such a diminution in size of the cerium-iron crystals can be obtained that, on, the one hand, the pyrophoric properties are not substantially influenced, while, on the other hand, the cerium-iron crystals can slip past one another. during extrusion without shattering so that an increase in eutectic matrix is notnecessary.
  • the process according to the present invention can therefore be carried out by utilizing cerium-iron alloys with an-ironcontent of more than and up to and an inoculant addition, e. g. zirconium.
  • an inoculant addition e. g. zirconium.
  • the .amount of this addition must not be so, large that it substantially affects the pyrophoric properties of the alloy. Additions of up to 1% zirconium, for example, are sufficient.
  • Particularlyadvantageousinoculant additions are such elements that do not form with the other alloying elements any alloy constituents which are-liquid below the extrusion temperature. Alloying constituents which are liquid at the extrusion temperature have a detrimental effect on the extrusion operation.
  • cerium this term is intended to include the misch metal customary in the trade which, in addition to cerium, is always accompanied by other rare earths, for example lanthanum.
  • the high oxidizability of the cerium-iron alloys reduces their lastingness.
  • the alloys are destroyed in time by oxidation from the air, in particular under the high temperatures of hot and moist climates.
  • Cerium-iron flints therefore usually have at protecting covering. It has now been found that the lastingness is increased to an extraordinary degree if the cerium-iron alloy is plunged in oil when in hot condition. This can easily be effected in the case of extruded flints by leading into oil the rod of material delivered hot from the extrusion press, with or without an intermediate passage through an atmosphere of inert gas which, for example, may be argon, hydrogen or nitrogen. This method of improving the lastingness, however, is not limited to extruded flints.
  • the lastingness can also be improved in the case of extruded material by surrounding the ingot with a coating metal and then extruding it, so that the emerging rod of cerium-iron alloy is surrounded by a thin coating of the protecting metal.
  • Aluminium has been found specially suitable for this purpose.
  • the ingot can either be wrapped with aluminum foil, introduced into an aluminium tube, or have aluminium cast around it.
  • This compounded material is heated to approximately 1200 C., preferably 1 150 C. while the temperature of the mold is approximately 100 C. The period of cooling until the mold is opened amounts to approximately 30 minutes.
  • the ingots thus obtained have a temperature of approximately 450 C. and are then subjected to the action of an extrusion process operating under a pressure of approx imately 16,000 leg/cm. in the same manner as described in Example 1.

Landscapes

  • Engineering & Computer Science (AREA)
  • Metallurgy (AREA)
  • Chemical & Material Sciences (AREA)
  • Organic Chemistry (AREA)
  • Extrusion Of Metal (AREA)

Description

United States Patent PROCESS OF PRODUCING FLFNTS BY MEANS OF EX I-RUSION Walter Bungardt, Essen-Bredeney, Germany, assignor. to Th. Goldschmidt A.-G. Chemische Fabriken, Essen, Germany, a German corporation 4 Claims. (Cl. 75152) This invention refers to the manufacture of pyrophoric flint material in rod or like shape and has. as one of its primary objects to provide means affording subjection of an ingot of suitable alloy to an extrusion press having a die opening whose cross-section corresponds to that of the finished flint rod.
It is another object of the inventionto-p rovidemeans conducive we most simple and economical production of flint material in rod formation or like shapes,,which is markedly improved in its pyrophoric propertiesand substantially free from any objectionable impurities.
It is a further object affording the manufacture of flint material with improved exactitude of size without the necessity of machining or other subsequent working which would cause additional expense and considerable delay in the obtainment of the desired end product.
Cerium-iron alloy flints are usually made by casting. It has been proposed to make flints of this kind by the extrusion process which is more economical than casting. The known attempts inthisv direction have failed. It was found that the pyrophoric properties of the alloy were lost during the extrusion process, hence the process has been described intechnical literature as completely useless.
The present invention proceeds from the recognition that the diminution of pyrophoric properties during extrusion is to be attributed to the fact that, on extrusion, the cerium-iron crystals, to which the pyrophoric action of the cerium-iron alloys is to be ascribed, are shattered and that consequently a larger quantity of eutectic matrix is necessary in order to embed sufliciently the fragments of the cerium-iron crystals so that they are protected against breaking out when subjected to friction by the friction Wheel of a lighter. Researches have shown that the necessary quantity of eutectic matrix increases with the increase in size of the cerium iron crystals in the ingot introduced into the extrusion press.
The eutectic matrix has not only the task of embedding the cerium-iron crystals and protecting them from breaking away, but also of increasing the pyrophoric properties of the cerium-iron crystals. The eutectic matrix is readily oxidizable, but oxidation manifests itself not in spark formation on friction but only in heat production; however this heat production favors the flaming of the pyrophoric crystal fragments. The best cerium-iron alloy for flints produced by casting consists of about 30 to 40% iron, the remainder being cerium. The amount of eutectic matrix increases with the decrease in the iron content.
In the process for the production of pyrophoric flints from cerium-iron alloys, by means of extrusion presses according to the present invention, the iron content may be lowered to to 25% of the total alloy-age. It was found that with ingots with an iron content lowered to from 15 to 25%, when they are produced in a normal manner, such a quantity of eutectic groundmass or matrix of the invention to providemeans.
ice
2. must be on hand that the fragments'or fission-products of the cerium-iron crystals resulting from extrusion pressing remain sufliciently anchored or tied in the matrix. The required amount ofeutectic groundm-ass or matrix for extrusion pressing may be reduced as the cerium-ironcrystals are-correspondingly smaller in the ingot used for extrusion pressing.
The crystals shouldnot be below a minimum size, otherwise they lose their pyrophoric properties. It has now been found, however, that by the use of inoculant' additions, i. e. additions resulting from the production of more numerous but smaller crystals, or by accelerated cooling of the ingot, such a diminution in size of the cerium-iron crystals can be obtained that, on, the one hand, the pyrophoric properties are not substantially influenced, while, on the other hand, the cerium-iron crystals can slip past one another. during extrusion without shattering so that an increase in eutectic matrix is notnecessary. The process according to the present invention can therefore be carried out by utilizing cerium-iron alloys with an-ironcontent of more than and up to and an inoculant addition, e. g. zirconium. The .amount of this addition must not be so, large that it substantially affects the pyrophoric properties of the alloy. Additions of up to 1% zirconium, for example, are sufficient.
Particularlyadvantageousinoculant additions are such elements that do not form with the other alloying elements any alloy constituents which are-liquid below the extrusion temperature. Alloying constituents which are liquid at the extrusion temperature have a detrimental effect on the extrusion operation.
As the melting point of cerium-iron alloys decreases with reduction in the iron contents, such a reductionhas advantages during casting. It diminishes, for example, the loss by burning. Onthe other hand, it diminishes also" the hardness of the alloy so that the friction wheel of the lighter rubs more severely against the flint and thereforeuses'it up more rapidly. It therefore alloys with a low iron contentiare used in accordance with the invention, it is useful to add to them hardness-increasing elements, for example tin, magnesium, cadmium or zinc, in a quantity which does not substantially affect the pyrophoric properties of the alloy.
Where reference has been made above to cerium, this term is intended to include the misch metal customary in the trade which, in addition to cerium, is always accompanied by other rare earths, for example lanthanum.
The high oxidizability of the cerium-iron alloys reduces their lastingness. The alloys are destroyed in time by oxidation from the air, in particular under the high temperatures of hot and moist climates.
Cerium-iron flints therefore usually have at protecting covering. It has now been found that the lastingness is increased to an extraordinary degree if the cerium-iron alloy is plunged in oil when in hot condition. This can easily be effected in the case of extruded flints by leading into oil the rod of material delivered hot from the extrusion press, with or without an intermediate passage through an atmosphere of inert gas which, for example, may be argon, hydrogen or nitrogen. This method of improving the lastingness, however, is not limited to extruded flints.
The lastingness can also be improved in the case of extruded material by surrounding the ingot with a coating metal and then extruding it, so that the emerging rod of cerium-iron alloy is surrounded by a thin coating of the protecting metal. Aluminium has been found specially suitable for this purpose. The ingot can either be wrapped with aluminum foil, introduced into an aluminium tube, or have aluminium cast around it.
The following examples are given to demonstrate the features of the invention:
'Ingots of a diameter of approximately 30 mm. are
produced by pouring into special steel ladles or molds, packed with sand, molten compounded material consisting of approximately 30 parts by weight of iron while misch metal constitutes the remainder of said material.
This compounded material is heated to approximately 1200 C., preferably 1 150 C. while the temperature of the mold is approximately 100 C. The period of cooling until the mold is opened amounts to approximately 30 minutes.
The ingots thus obtained have a temperature of approximately 450 C. and are then subjected to the action of an extrusion process operating under a pressure of approx imately 16,000 leg/cm. in the same manner as described in Example 1.
Many other changes and modifications of the invention may be made without limiting the same and without departing from the scope of the invention.
This application is a continuation-in-part of application Serial No. 117,069, filed September 21, 1949, now Patent No. 2,660,301.
What is claimed as new and desired to be secured by Letters Patent is:
1. The process of producing flint material in rod formation comprising the steps of preparing an ingot by adding to an alloy containing approximately 25% to 40% iron, with cerium being the remainder, an inoculant suflicient to influence the crystal formation of said alloy without substantially changing the pyrophoric properties thereof,
' and subjecting said ingot thus prepared to the action of an extrusion press under a pressure of about 16,000 kg./cnr. and at a temperature of about 450 C. for obtaining an extruded material upon discharge of the latter through .a die opening having a cross-section corresponding to that of the finished flint rod.
2. In the process of producing flint material in rod formation; the step of preparing an ingot by adding to an alloy containing approximately 25% to 40% iron, with cerium being the remainder, approximately 0.05% to 1% of zirconium as an inoculant, whereby the crystal formation of said alloy is influenced without substantially changing the pyrophoric properties thereof.
*3. In the process of producing flint material in rod formation; the steps of adding to an alloy containing approximately 25% to 40% iron, with cerium being the remainder, an inoculant sufficient to influence the crystal formation of said alloy, further adding at least one hardness-increasing element selected from the group consisting of tin, magnesium, cadmium and zinc sufficient to obviate any substantial decrease of the pyrophoric properties of said alloy, and thereafter forming said alloy into an ingot prior to its transformation to flint material in rod formation.
4. The process of producing flint material in rod formation comprising the steps of preparing an ingot by adding to an alloy containing approximately 25% to 40% iron, with cerium being the remainder, approximately .1=5% of zirconium as an inoculant, whereby the crystal formation of said alloy is influenced without substantially changing the pyrophoric properties thereof, and subjecting said ingot thus prepared to the action of an extrusion press under a pressure of about 16,000 kg./crn. and at a temperature of about 450 C. for obtaining an extruded material upon discharge of the latter through a die opening having a cross-section corresponding to that of the finished flint rod.
References Cited in the file of this patent FOREIGN PATENTS

Claims (1)

1. THE PROCESS OF PRODUCING FLINT MATERIAL IN ROD FORMATION COMPRISING THE STEPS OF PREPARING AN INGOT BY ADDING TO AN ALLOY CONTAINING APPROXIMATELY 25% TO 40% IRON, WITH CERIUM BEING THE REMAINDER, AN INOCULANT SUFFICIENT TO INFLUENCE THE CRYSTAL FORMATON OF SAID ALLOY WITHOUT SUBSTANTIALLY CHANGING THE PYROPHORIC PROPERTIES THEREOF, AND SUBJECTING SAID INGOT THUS PREPARED TO THE ACTION OF AN EXTRUSION PRESS UNDER A PRESSURE OF ABOUT 16,000 KG./CM.2 AND AT A TEMPERATURE OF ABOUT 450* C. FOR OBTAINING AN EXTRUDED MATERIAL UPON DISCHARGE OF THE LATTER THROUGH A DIE OPENING HAVING A CROSS-SECTION CORRESPONDING TO THAT OF THE FINISHED FLINT ROD.
US381738A 1948-09-28 1953-09-22 Process of producing flints by means of extrusion Expired - Lifetime US2762707A (en)

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
NL2762707X 1948-09-28

Publications (1)

Publication Number Publication Date
US2762707A true US2762707A (en) 1956-09-11

Family

ID=19875625

Family Applications (1)

Application Number Title Priority Date Filing Date
US381738A Expired - Lifetime US2762707A (en) 1948-09-28 1953-09-22 Process of producing flints by means of extrusion

Country Status (1)

Country Link
US (1) US2762707A (en)

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2864160A (en) * 1954-10-11 1958-12-16 Goldschmidt Ag Th Method of continuously protecting pyrophoric flint material manufactured by extrusion
US2961763A (en) * 1957-01-16 1960-11-29 Ronson Metals Corp Mischmetal-magnesium pellets and process for manufacturing the same

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB190316853A (en) * 1903-07-31 1904-05-26 Carl Freiherr Auer Vo Welsbach Manufacture of Metallic Alloys having Pyrophoric Action and their application to the purposes of Ignition and Illumination.
GB567445A (en) * 1943-08-06 1945-02-14 Henry Kent Flint alloy

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB190316853A (en) * 1903-07-31 1904-05-26 Carl Freiherr Auer Vo Welsbach Manufacture of Metallic Alloys having Pyrophoric Action and their application to the purposes of Ignition and Illumination.
GB567445A (en) * 1943-08-06 1945-02-14 Henry Kent Flint alloy

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2864160A (en) * 1954-10-11 1958-12-16 Goldschmidt Ag Th Method of continuously protecting pyrophoric flint material manufactured by extrusion
US2961763A (en) * 1957-01-16 1960-11-29 Ronson Metals Corp Mischmetal-magnesium pellets and process for manufacturing the same

Similar Documents

Publication Publication Date Title
JP3415987B2 (en) Molding method of heat-resistant magnesium alloy molded member
US4689090A (en) Superplastic aluminum alloys containing scandium
JPH02503331A (en) Magnesium alloy with high mechanical resistance and manufacturing method by rapid solidification of the alloy
AU753538B2 (en) Die casting magnesium alloy
JP3522963B2 (en) Method for producing heat-resistant magnesium alloy member, magnesium alloy used therefor, and magnesium alloy molded member
GB1499934A (en) Alloy treatment
US4053304A (en) Flux for refinement of pro-eutectic silicon crystal grains in high-silicon aluminum alloys
US4732610A (en) Al-Zn-Mg-Cu powder metallurgy alloy
US2762707A (en) Process of producing flints by means of extrusion
US2660301A (en) Process for the manufacture of cerium-iron-alloy flints
US5088544A (en) Process for the lost-foam casting, under controlled pressure, of metal articles
US3004331A (en) Aluminum base alloy powder product
NO175543B (en) Silicon-based alloy, method of making such alloy, and method of producing consolidated products from silicon-based alloy
US4990310A (en) Creep-resistant die cast zinc alloys
JP2789035B2 (en) Method for producing aluminum / silicon alloy article
US4175918A (en) Elongate consolidated article and method of making
US2792301A (en) Process of manufacturing flint or like pyrophoric material in extrusion presses
JPH02149631A (en) Low thermal expansion aluminum alloy having excellent wear resistance and heat conductivity
USRE25558E (en) Pyrophoric alloys without iron
US3445920A (en) Aluminum base alloy production
Carnahan et al. Advances in Thixomolding
US3182390A (en) Method of die-expressing a magnesiumbase alloy
US4071359A (en) Copper base alloys
US3203790A (en) Extruded flints and process for making same
US4089706A (en) Method of producing flint