US2306164A - Extrusion device - Google Patents
Extrusion device Download PDFInfo
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- US2306164A US2306164A US322879A US32287940A US2306164A US 2306164 A US2306164 A US 2306164A US 322879 A US322879 A US 322879A US 32287940 A US32287940 A US 32287940A US 2306164 A US2306164 A US 2306164A
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- reservoir
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- core
- tubing
- extrusion
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- C—CHEMISTRY; METALLURGY
- C03—GLASS; MINERAL OR SLAG WOOL
- C03B—MANUFACTURE, SHAPING, OR SUPPLEMENTARY PROCESSES
- C03B17/00—Forming molten glass by flowing-out, pushing-out, extruding or drawing downwardly or laterally from forming slits or by overflowing over lips
- C03B17/04—Forming tubes or rods by drawing from stationary or rotating tools or from forming nozzles
Definitions
- FIG. 1 A first figure.
- FIG. 5 H. c. HARRISON 2 Sheets-Sheet 2 l/VVE/VTOR H. CHARR/SON BY FIG. 5
- This invention relates to an extrusion device and more particularly to a device for producing vitreous tubing for various purposes.
- An object of the invention is to fabricate accurate internal diameter tubing'o'n a mass pro- I duction basis.
- Another object of the invention is to facilitate the manufacture of glass tubing of uniform quality adaptable for devices employing an oscillatory element.
- a further object of the invention is to overcome dimcultles of corrosion and oxidation in the device which affects the prescribed limits of the diameters of the tubing.
- a supply of material adapted to be. formed into tubular effective seal to prevent. the entrance of gas adjacent the extrusion head which might cause imperfection's, such as gas cavities, in the extruded tubing.
- a fluid medium preferably an' inert gas, under high pressure, is supplied to the inlet of the reservoir to force or extrude the plastic material through the head and produce tubing of the required inner and outer diameter accuracies to within .0015 inch.
- the high pressure gaseous propelling medium is also supplied to the furnace in order to equalize the pressure on the.
- a further feature of the invention is concerned the supply of material extruded in the device.
- Fig. 1 is a view in cross-section of one form of the tube extrusion device of this invention showing the details of assembly of an extrusion head and associated elements contained within an outer housing for producing accurate diameter tubing;
- Fig. 2 is a partial view in cross-section of the device including a modification of -the invention in which a removable refill shell is associated with the extrusion head;
- Fig. 3 is an enlarged view in cross-section o the plates of the extrusion head showing the planary emergence faces of the core and die portions of the plates;
- Fig. 4 is a plan view showing the appearance of the cooperating 'plates of the extrusion head in a direction toward the lower plate of Fig. 3
- Fig. 5 shows another form of the invention with parts in cross-section to illustrate the exj trusion of plastic material into tubular lengths;
- the tubulating apparatus of this invention involves a cylindrical metallic reservoir or receptacle [0 adapted to be filled with a material which can be rendered plastic or semiviscous, such as various glasses, clear resins and similar materials, so that it may be extruded to the dereservoir is provided with a conical throat or outthe invention relates to assembly in which the extension cap permits the let i! at the lower end which leads into a pair .of cooperating core and die plates [2 and I3,
- the glass, or other material is shaped in any desired form,such as agtube, havingaccur ate inner and outer diameters.
- the reservoir. andextrusion head are enclosed in a furnace housing. ll provided with a removclosed bythe cap screw enters'-acylindrlcalex-.
- furnace housing and surrounds a heater, such as aresistance wire heater, shown schematically at l9, which is located around the reservoir to heat the same by conduction and thereby reduce the material in the reservoir to a plastic state.
- a heater such as aresistance wire heater, shown schematically at l9, which is located around the reservoir to heat the same by conduction and thereby reduce the material in the reservoir to a plastic state.
- the cover plate I is provided with a central aperture through which extends a removable sleeve member having a circular flange 2
- the sleeve member is drilled longitudinally at equidistant points to receive guide rods 22 which are anchored in the outlet portion of the reservoir it. These rods extend through registering apertures, such as 23, in the core and die plates of the extrusion head and insure accurate alignment and true concentricity of the plates.
- the rods are provided with threaded ends extending beyond the flange 2
- This arrangement forms a unitary assembly of the reservoir and extrusion head and facilitates the removal, cleaning and replacing of the extrusion head plates. Furthermore, this construction escapes difficulties of corrosion and welding of threaded connections in the high temperature zone of the furnace.
- the plates l2 and I3 should be formed of a high temperature resistant metal or alloy, such as platinum-iridium or other suitable alloy. Such an alloy also resists oxida- .on the core plate l2 which extends beyond the surface of the plate. 'A plurality of tapered holes 2! are drilled through the plate [,2 around the central core to form passageways in the core plate for the extrusion of the plastic material in the reservoir.
- the core 24 is also tapered for a short distance beyond the lower surface of the plate but the termination of the core is a solid cylinder 26 with the flat surface 21 at right angles with respect to the surface of the cylinder 20.
- the die plate or ring I3 is provided with a central cylindrical aperture 28 adjacent to the surface 29 and coaxial with the peripheryof -the 'plate. This aperture connects with a tapering aperture 30, the larger diameter thereo coacting'with the apertures in the core p te l2.
- the guide holes 23 may be drilled to insure concentric relation of the plates when placed in position in the extrusion device.
- Thefinal processing of the plates l2 and II is the finishing and polishing of the contactsurfaces of the'core 24 and the inner walls of the apertures and the lapping of the surfaces 21 and 20 to insure a positive geometrical plane surface relation at the emergence faces of the plates.
- Thes operations produce sharp clearance edges for the exit of the extrusion head whereby adherence of the semi-solid tubing is prevented and constant uniform diameters maintained in the resultant tubing.
- the pressure medium employed for forcing the plastic material through the extrusion head may be any, suitable fluid but an inert gaseous medium, such as nitrogen,is preferred since it is more adaptable to the proposed construction and easily controlled.
- the nitrogen is supplied to the reservoir in through the threaded inlet port 3
- an annular base 33 receives the threaded ends of the guide rod: 22 and is provided with a conic inner surface 34 to direct the plastic material. through the extrusion head.
- the upper portion ofthe base is cylindrical and slightly larger in'diameter than the wider end of the conical cavity formed by the wall 34 and the rim of the base is beveled.
- a thin walled metallic tube or sleeve 35 when filled with a solid mass of material which is to be extruded, forms a refill container, or magazine which may be inserted through-the opening of the furnace closed by thecap screw 16 and is readily removable when empty.
- the tube 35 is provided with a reduced end portion 36 formed to coincide with the beveled and cylindrical surfaces of the base 33 to produce a tight telescopic joint to prevent the entrance of gas and the leakage of plastic material from the reservoir.
- This arrangement enhances the replenishing of the extrusion device with more material to be extruded, or, if desired, to substitute a different material. Since the refill contains the material in solid form', it is apparent that the furnace may be stocked expediently by providing a supply of .refills with the desired material to be extruded.
- FIG. 5' another form of the invention is shown'to illustrate the. operation of the extruding or tubulating device for producing accurate diameter tubing.
- a tubular reservoir 31 threaded at both ends is provided with an apertured cap 30 at the upper end and a cap 39 at the lower end having a plurality of orifices surrounding a central corepiece '40 of the same configuration as shown in Fig. 3.
- Ametalllc sleeve ll surrounds the reservoir to space the end caps andfacilitate the removal of the reservoir.
- a die plate 42 is secured to the core :cap 39 and also to a cover plate of the furnace housing 43 to support the extruding device in
- the cap ll re ceives a pipe connection 4 4 which communicates with the nitrogenisupply for producing a high pressure in the reservoir 31.
- a similar pipe 4' connected to the gas supply is Joined to the furnace to induce the same pressure therein and equalize the pressure on the parts of the exerable length by more or less than .0015 inch.
- Such atubing may be produced by filling the reservoir, such as 31 in Fig. 5, with a vitreous material, such as lead glass 46, either in a plastic or solid state, and energizing the heater IS in the furnace to maintain a temperature between 600 to 700 C.
- a vitreous material such as lead glass 46
- the nitrogen gas supply under a desired pressure, between 500 to 1000 pounds per square inch, is injected into the reservoir and the furnace, the pressure being high enough to attain a satisfactory rate of production, since the rate of flow is a. function of temperature and pressure. Assuming the glass 46 is of the proper consistency fortubulating' at 660 C.
- the tubing 41 emerging from the extrusion head is formed at the rate of ten feet per hour and the internaldiameter 41 does not vary from the limit of 10015 inch.
- the rate of flow permits the tubing to solidify by cooling on contact with air and no elongation occurs if the length of tubing does not attain too great a weightf'l'ubing having lengths" of two feet are readily produced without elongation. If high temperatures are employed or greater lengths desired, some counterbalancing method, such as a spring support for the tubing, may beused to onset attendant elongation of the glass tubing.
- a tubulating device including reservoir within said housing,.a sleeve member supported by and extending into said housing, guide members extending between said reservoir and sleeve member, a pair of complementary extrusion plates slidably positioned on said guide members, and means external to said housing for rigidly clamping said plates in concentric relation.
- a vitreous tube extruding device comprising a hollow chamber, a reservoir for a vitreous mass contained within said chamber, means for heating said mass mountedin said chamber, a core die plate adjacent the exit end of said reservoir and also mounted within said chamber, a ring die plate surrounding the core of said core die plate and mounted in juxtaposed relation therewith to constitute a tube forming head for the heated mass, and means for injecting a uniform high pressure gaseous medium into said reservoir and chamber to control the flow of said vitreous mass,
- An extrusion device comprising a reservoir having an outlet port adapted to contain a vitreous mass which is to be formed into tubing when in a plastic state, a housing enclosing said reservoir, heating means between said housing and reservoir, said reservoir and housing adapted to contain a gaseous medium under uniform high pressure, and an extrusion head coaxially mount-' ed at said outlet .port including a pair of plates in complementary relation, one of said plates having a central projecting core with apertures surrounding the same, and the other plate having a central aperture coaxial with said core, the emergence surfaces of said core and other plate being in a single geometrical plane.
- An extrusion device comprising a reservoir having an outlet port adapted to contain a glass mass which is to be formed into tubing when in a plastic state, a housing surrounding said reservoir, heating means between said housing and reservoir, said reservoir and housing being adapted to receive a supply of nitrogen under high pressure to be injected therein, an extrusion head mounted at said outlet port including a pair of platinum-iridium alloy plates in complemen-' tary relation, one of said plates having a central projecting core with apertures surroundin the same and the other. plate having a central aperture coaxial with said core, the emergence surfaces of said core and other plates being in a single geometrical plane.
- Anextrusion device comprising a reservoir having an outlet port adapted to contain a glass Y mass which is to be formed into. tubing when .-in,ga plastic state. a housing'surrounding said reservoir, heating means between said housing and reservoir, said reservoir and housing adapted tobe filled with a supply of nitrogen imder high uniform pressure, a platinumiridium alloy. extrusion head comprising a' core plate and a ring 1 die in complementary relationto extrude glass a housing, a
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- Chemical & Material Sciences (AREA)
- Engineering & Computer Science (AREA)
- Materials Engineering (AREA)
- Organic Chemistry (AREA)
- Extrusion Moulding Of Plastics Or The Like (AREA)
Description
2 Sheets-Sheet 1 Filed March 8, .1940
FIG.
v 5 3 2 3 4 v m a a a 2 Z I! 0 i. M n 1 2 I a v I 3 4 //////W///// Ill m 2 m, k m A I I flHull l INVENTOR By H. c. HARRISON MAI-eat M ATZORNEV 'Dec. 22, 1942.
- H. c. HARRISON 2 Sheets-Sheet 2 l/VVE/VTOR H. CHARR/SON BY FIG. 5
A TTORNEV Patented Dec. 22, 1942 Henry 0. Harrison, Port Washington, N. Y., a:-
I signor to Bell Telephone Laboratories, Incorporated, New York, N. Y., a corporation of New York 7 Application March 8, 1940, Serial No. 322,879
5 Claims. (01. 49-17.1)
This invention relates to an extrusion device and more particularly to a device for producing vitreous tubing for various purposes.
An object of the invention is to fabricate accurate internal diameter tubing'o'n a mass pro- I duction basis.
Another object of the invention is to facilitate the manufacture of glass tubing of uniform quality adaptable for devices employing an oscillatory element.
- A further object of the invention is to overcome dimcultles of corrosion and oxidation in the device which affects the prescribed limits of the diameters of the tubing.
. In accordance with this invention, a supply of material adapted to be. formed into tubular effective seal to prevent. the entrance of gas adjacent the extrusion head which might cause imperfection's, such as gas cavities, in the extruded tubing.
Theseand other features and advantages of this invention will be apparent from the following detailed description taken in connection with the accompanying drawings:
lengths is contained in a hollow reservoir or receptacle'and maintained in. a plastic or 'semiviscous condition by a furnace which surrounds the receptacle. The outlet of the reservoir is pro- ..vided with complementary core and die plates forming an extrusion head in which the emergence facesof the plates are ground and polished to a smooth surface which lies in a single plane and their edges are definitely sharp to avoid adherence of the plastic material to the extrusion head. A fluid medium, preferably an' inert gas, under high pressure, is supplied to the inlet of the reservoir to force or extrude the plastic material through the head and produce tubing of the required inner and outer diameter accuracies to within .0015 inch. The high pressure gaseous propelling medium is also supplied to the furnace in order to equalize the pressure on the.
tothe exterior of therfurnaceto facilitate the removal and cleaning of the die plates of the head.
Another feature of removal of thehead and reservoir as a unit to facilitate changes in tube diameter or material.
v A further feature of the invention is concerned the supply of material extruded in the device. In.
this arrangement the furnace cap supports the extrusion head and asuperimposed cup member which is adapted to receive a thin metallicshell or casing containing a mass of material in solid form. Th telescopic jointprovided between the :cup member and the refill casing provides an Fig. 1 is a view in cross-section of one form of the tube extrusion device of this invention showing the details of assembly of an extrusion head and associated elements contained within an outer housing for producing accurate diameter tubing;
Fig. 2 is a partial view in cross-section of the device including a modification of -the invention in which a removable refill shell is associated with the extrusion head; i
Fig. 3 is an enlarged view in cross-section o the plates of the extrusion head showing the planary emergence faces of the core and die portions of the plates;
Fig. 4 is a plan view showing the appearance of the cooperating 'plates of the extrusion head in a direction toward the lower plate of Fig. 3
Fig. 5 shows another form of the invention with parts in cross-section to illustrate the exj trusion of plastic material into tubular lengths;
in accordance with the teachings of this invention. 1
Referring to the drawings and Fig. 1 particularly, the tubulating apparatus of this invention involves a cylindrical metallic reservoir or receptacle [0 adapted to be filled with a material which can be rendered plastic or semiviscous, such as various glasses, clear resins and similar materials, so that it may be extruded to the dereservoir is provided with a conical throat or outthe invention relates to assembly in which the extension cap permits the let i! at the lower end which leads into a pair .of cooperating core and die plates [2 and I3,
' respectively. which form an extrusion head with 'a removable refill ormagazine to replenish whereby. the glass, or other material, is shaped in any desired form,such as agtube, havingaccur ate inner and outer diameters.
The reservoir. andextrusion headare enclosed in a furnace housing. ll provided with a removclosed bythe cap screw enters'-acylindrlcalex-.
- tension ll of the housing which forms an internal guide for the upper end of the reservoir II.
furnace housing and surrounds a heater, such as aresistance wire heater, shown schematically at l9, which is located around the reservoir to heat the same by conduction and thereby reduce the material in the reservoir to a plastic state.
The cover plate I is provided with a central aperture through which extends a removable sleeve member having a circular flange 2| which is secured to the cover plate by bolts.- The sleeve member is drilled longitudinally at equidistant points to receive guide rods 22 which are anchored in the outlet portion of the reservoir it. These rods extend through registering apertures, such as 23, in the core and die plates of the extrusion head and insure accurate alignment and true concentricity of the plates. The rods are provided with threaded ends extending beyond the flange 2| to receive nuts which exert clamping pressure upon the sleeve member and the plates l2 and I3, to insure rigidity and constant position of the plates in eooperativerelation. This arrangement forms a unitary assembly of the reservoir and extrusion head and facilitates the removal, cleaning and replacing of the extrusion head plates. Furthermore, this construction escapes difficulties of corrosion and welding of threaded connections in the high temperature zone of the furnace.
Since the extrusion head is affected by high temperature due to its location within the furnace, it is essential that the plates l2 and I3 should be formed of a high temperature resistant metal or alloy, such as platinum-iridium or other suitable alloy. Such an alloy also resists oxida- .on the core plate l2 which extends beyond the surface of the plate. 'A plurality of tapered holes 2! are drilled through the plate [,2 around the central core to form passageways in the core plate for the extrusion of the plastic material in the reservoir. The core 24 is also tapered for a short distance beyond the lower surface of the plate but the termination of the core is a solid cylinder 26 with the flat surface 21 at right angles with respect to the surface of the cylinder 20. The die plate or ring I3 is provided with a central cylindrical aperture 28 adjacent to the surface 29 and coaxial with the peripheryof -the 'plate. This aperture connects with a tapering aperture 30, the larger diameter thereo coacting'with the apertures in the core p te l2.
when a suitable gauge is interposed in'the cylindrical gap between the core 28 and the surface 28 of the die plate I! the guide holes 23 may be drilled to insure concentric relation of the plates when placed in position in the extrusion device. Thefinal processing of the plates l2 and II is the finishing and polishing of the contactsurfaces of the'core 24 and the inner walls of the apertures and the lapping of the surfaces 21 and 20 to insure a positive geometrical plane surface relation at the emergence faces of the plates.
Thes operations produce sharp clearance edges for the exit of the extrusion head whereby adherence of the semi-solid tubing is prevented and constant uniform diameters maintained in the resultant tubing.
The pressure medium employed for forcing the plastic material through the extrusion head may be any, suitable fluid but an inert gaseous medium, such as nitrogen,is preferred since it is more adaptable to the proposed construction and easily controlled. The nitrogen is supplied to the reservoir in through the threaded inlet port 3| under high pressure of the order of 500 to 1000 pounds per square inch, depending on the material and the speed of production. Since the high pressure may be detrimental with respect to the wall of the reservoir, it is proposed to inject the same pressure of gas into the furnace through a bypass opening 32 so that the pressure on the reservoir and vitreous material 1s equalized and the construction rendered safe and efficient.
' in Fig. 2; the sleeve member 20 and the extrusion In a modification of the invention, as shown head comprising the plates i2 and I3 are suprigid relation to the furnace.
ported in the same relation as in Fig. 1, but the reservoir is transformed to increase the efliciency and versatility of the extrusion device. In this arrangement, an annular base 33 receives the threaded ends of the guide rod: 22 and is provided with a conic inner surface 34 to direct the plastic material. through the extrusion head.
The upper portion ofthe base is cylindrical and slightly larger in'diameter than the wider end of the conical cavity formed by the wall 34 and the rim of the base is beveled. A thin walled metallic tube or sleeve 35, when filled with a solid mass of material which is to be extruded, forms a refill container, or magazine which may be inserted through-the opening of the furnace closed by thecap screw 16 and is readily removable when empty. The tube 35 is provided with a reduced end portion 36 formed to coincide with the beveled and cylindrical surfaces of the base 33 to produce a tight telescopic joint to prevent the entrance of gas and the leakage of plastic material from the reservoir.
This arrangement enhances the replenishing of the extrusion device with more material to be extruded, or, if desired, to substitute a different material. Since the refill contains the material in solid form', it is apparent that the furnace may be stocked expediently by providing a supply of .refills with the desired material to be extruded.
Furthermore, theequalized pressure of nitrogen In' Fig. 5' another form of the invention is shown'to illustrate the. operation of the extruding or tubulating device for producing accurate diameter tubing. In this flgureya tubular reservoir 31 threaded at both ends is provided with an apertured cap 30 at the upper end and a cap 39 at the lower end having a plurality of orifices surrounding a central corepiece '40 of the same configuration as shown in Fig. 3. Ametalllc sleeve ll surrounds the reservoir to space the end caps andfacilitate the removal of the reservoir. A die plate 42 is secured to the core :cap 39 and also to a cover plate of the furnace housing 43 to support the extruding device in The cap ll re ceives a pipe connection 4 4 which communicates with the nitrogenisupply for producing a high pressure in the reservoir 31. A similar pipe 4' connected to the gas supply is Joined to the furnace to induce the same pressure therein and equalize the pressure on the parts of the exerable length by more or less than .0015 inch.
Such atubing may be produced by filling the reservoir, such as 31 in Fig. 5, with a vitreous material, such as lead glass 46, either in a plastic or solid state, and energizing the heater IS in the furnace to maintain a temperature between 600 to 700 C. When the glass mass 46 is in the proper condition for extrusion the nitrogen gas supply under a desired pressure, between 500 to 1000 pounds per square inch, is injected into the reservoir and the furnace, the pressure being high enough to attain a satisfactory rate of production, since the rate of flow is a. function of temperature and pressure. Assuming the glass 46 is of the proper consistency fortubulating' at 660 C. and the pressure of gas is 1000 pounds per square inch, the tubing 41 emerging from the extrusion head is formed at the rate of ten feet per hour and the internaldiameter 41 does not vary from the limit of 10015 inch. The rate of flow permits the tubing to solidify by cooling on contact with air and no elongation occurs if the length of tubing does not attain too great a weightf'l'ubing having lengths" of two feet are readily produced without elongation. If high temperatures are employed or greater lengths desired, some counterbalancing method, such as a spring support for the tubing, may beused to onset attendant elongation of the glass tubing.
The accuracy obtained with any desired diameter of tubing is attributed primarily to the constantly sharp true edges of the high temperature resistant plates and the plenary emergence surfaces of the core and die plates of the extrusion head. Any irregularity of internal diameter of the tubing would detract from the usefulness of the tubing for the switching device referred to but the tubing produced by the extrusion device of thisinvention has met all mechanical testsfor this application and there are many equally pertinent mechanisms where thetubing produced may be employed with advantage from the standpoint of eiilciency, long life and utility;
While the invention has been disclosed with respect to certain preferred forms, it is, of course,
imderstood that modifications can be made in the components of the extrusion device without from the scope of the invention as de-' fined in the appended claims.
departing what is claimed is:
1. A tubulating device including reservoir within said housing,.a sleeve member supported by and extending into said housing, guide members extending between said reservoir and sleeve member, a pair of complementary extrusion plates slidably positioned on said guide members, and means external to said housing for rigidly clamping said plates in concentric relation. a
2. A vitreous tube extruding device comprising a hollow chamber, a reservoir for a vitreous mass contained within said chamber, means for heating said mass mountedin said chamber, a core die plate adjacent the exit end of said reservoir and also mounted within said chamber, a ring die plate surrounding the core of said core die plate and mounted in juxtaposed relation therewith to constitute a tube forming head for the heated mass, and means for injecting a uniform high pressure gaseous medium into said reservoir and chamber to control the flow of said vitreous mass,
3. An extrusion device comprising a reservoir having an outlet port adapted to contain a vitreous mass which is to be formed into tubing when in a plastic state, a housing enclosing said reservoir, heating means between said housing and reservoir, said reservoir and housing adapted to contain a gaseous medium under uniform high pressure, and an extrusion head coaxially mount-' ed at said outlet .port including a pair of plates in complementary relation, one of said plates having a central projecting core with apertures surrounding the same, and the other plate having a central aperture coaxial with said core, the emergence surfaces of said core and other plate being in a single geometrical plane.
4. An extrusion device comprisinga reservoir having an outlet port adapted to contain a glass mass which is to be formed into tubing when in a plastic state, a housing surrounding said reservoir, heating means between said housing and reservoir, said reservoir and housing being adapted to receive a supply of nitrogen under high pressure to be injected therein, an extrusion head mounted at said outlet port including a pair of platinum-iridium alloy plates in complemen-' tary relation, one of said plates having a central projecting core with apertures surroundin the same and the other. plate having a central aperture coaxial with said core, the emergence surfaces of said core and other plates being in a single geometrical plane.
5. Anextrusion device comprising a reservoir having an outlet port adapted to contain a glass Y mass which is to be formed into. tubing when .-in,ga plastic state. a housing'surrounding said reservoir, heating means between said housing and reservoir, said reservoir and housing adapted tobe filled with a supply of nitrogen imder high uniform pressure, a platinumiridium alloy. extrusion head comprising a' core plate and a ring 1 die in complementary relationto extrude glass a housing, a
tubing of an internal diameter unvarying from .OOIS'inch-through its length, the emergent edges of said core and rin -diesbeing acute sharp andtheemergence sin'iaces thereof being in a true plane. and clamping means'securing said headtosaid-reservoirandhousing- HIRE; G. HARRISON.
Priority Applications (1)
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US322879A US2306164A (en) | 1940-03-08 | 1940-03-08 | Extrusion device |
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US322879A US2306164A (en) | 1940-03-08 | 1940-03-08 | Extrusion device |
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US2306164A true US2306164A (en) | 1942-12-22 |
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Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2486737A (en) * | 1945-11-14 | 1949-11-01 | Danner Edward | Method of manufacturing glassware |
US2616481A (en) * | 1946-12-30 | 1952-11-04 | Twells Robert | Device for mounting concentric bodies |
US2706365A (en) * | 1954-02-18 | 1955-04-19 | Owens Corning Fiberglass Corp | Feeder for molten thermoplastic material |
US2947028A (en) * | 1954-11-19 | 1960-08-02 | Owens Corning Fiberglass Corp | Apparatus for manufacture of fibrous glass |
US3266881A (en) * | 1962-10-09 | 1966-08-16 | Corning Glass Works | Glass delivery method |
US3303011A (en) * | 1966-03-30 | 1967-02-07 | Obra Kogaku Garasu Seizosho Kk | Process and apparatus for manufacturing elongated glass products |
US4199343A (en) * | 1977-08-29 | 1980-04-22 | Corning Glass Works | Mixing and injection molding hydrosilicates |
FR2503132A1 (en) * | 1981-04-02 | 1982-10-08 | Western Electric Co | METHOD AND INSTALLATION FOR EXTRUDING ARTICLES, IN PARTICULAR FROM A VISCOUS GLASS MASS MASS |
-
1940
- 1940-03-08 US US322879A patent/US2306164A/en not_active Expired - Lifetime
Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2486737A (en) * | 1945-11-14 | 1949-11-01 | Danner Edward | Method of manufacturing glassware |
US2616481A (en) * | 1946-12-30 | 1952-11-04 | Twells Robert | Device for mounting concentric bodies |
US2706365A (en) * | 1954-02-18 | 1955-04-19 | Owens Corning Fiberglass Corp | Feeder for molten thermoplastic material |
US2947028A (en) * | 1954-11-19 | 1960-08-02 | Owens Corning Fiberglass Corp | Apparatus for manufacture of fibrous glass |
US3266881A (en) * | 1962-10-09 | 1966-08-16 | Corning Glass Works | Glass delivery method |
US3303011A (en) * | 1966-03-30 | 1967-02-07 | Obra Kogaku Garasu Seizosho Kk | Process and apparatus for manufacturing elongated glass products |
US4199343A (en) * | 1977-08-29 | 1980-04-22 | Corning Glass Works | Mixing and injection molding hydrosilicates |
FR2503132A1 (en) * | 1981-04-02 | 1982-10-08 | Western Electric Co | METHOD AND INSTALLATION FOR EXTRUDING ARTICLES, IN PARTICULAR FROM A VISCOUS GLASS MASS MASS |
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