US2715683A - Ion source for a calutron - Google Patents

Ion source for a calutron Download PDF

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US2715683A
US2715683A US578280A US57828045A US2715683A US 2715683 A US2715683 A US 2715683A US 578280 A US578280 A US 578280A US 57828045 A US57828045 A US 57828045A US 2715683 A US2715683 A US 2715683A
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arc
shield
chamber
block
slit
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US578280A
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John G Backus
Peters Bernard
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J49/00Particle spectrometers or separator tubes
    • H01J49/26Mass spectrometers or separator tubes
    • H01J49/28Static spectrometers
    • H01J49/30Static spectrometers using magnetic analysers, e.g. Dempster spectrometer
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J49/00Particle spectrometers or separator tubes
    • H01J49/02Details
    • H01J49/10Ion sources; Ion guns
    • H01J49/12Ion sources; Ion guns using an arc discharge, e.g. of the duoplasmatron type
    • H01J49/126Other arc discharge ion sources using an applied magnetic field

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  • the present invention relates to the art of separating a polyisotope into a plurality of substantially mono-isotopic masses. More particularly, my invention relates to a calutron, a device wherein a polyisotopic substance is vaporized and then ionized under conditions causing a beam of positive ions to traverse an evacuated tank disposed between the pole pieces of a powerful magnet. The action of the magnetic flux causes the beam of ions to follow a curved path; ions of heavier isotopes tend to concentrate along the outer periphery of the curve, and ions of lighter isotopes follow the inner periphery of the curve.
  • a suitable collector in the path of the beam, preferably 180 from its source, it is possible to segregate and collect masses in which the distribution of isotopes has been radically changed or in which isotopes are substantially completely separated.
  • a calutron is useful for separating naturally occurring uranium containing U235 and U23S into two masses of which one is enriched with respect to U235 and the other is correspondingly impoverished.
  • a satisfactory device for generating a beam of ions may comprise a charge chamber in which a charge of material to be vaporized is heated, and an arc chamber having a lamentary cathode suitably positioned to strike an arc across the chamber and ionize the molecules of the vaporized polyisotope.
  • a lamentary cathode suitably positioned to strike an arc across the chamber and ionize the molecules of the vaporized polyisotope.
  • an accelerating electrode maintained at a highly negative potential is disposed in advance of the exit slit.
  • the function of the latter electrode is to attract the positive ions formed in the arc chamber and draw them through the exit slit with considerable velocity in the form of a narrow ribbon or beam which traverses the evacuated tank in a path normal to the direction of the ux in the magnetic eld formed between pole pieces of the magnet.
  • One object of the invention is to produce in a calutron a more stable beam of positive ions.
  • a further object of the invention is to provide a simple and compact ion source for a calutron.
  • Another object of the invention is to provide an ion source for a calutron in which a large percentage of vaporized material is ionized and formed in a beam.
  • An important feature of the invention resides in the combination of a diaphragm closing one side of the arc chamber and having an elongated slit disposed in register with a similar slit in a second diaphragm mounted closely adjacent the iirst diaphragm and maintained at a highly negative potential with respect thereto.
  • Another feature of the invention resides in disposing the accelerating electrode adjacent the bottom of a cupshaped depression formed in one Wall of the arc block. This feature has the advantage of preventing the random escape of ions from the arc chamber and increases the ice efficiency of the ion source in that substantially all of the ions formed in the arc chamber are drawn into the beam.
  • a further feature of the invention resides in a cylindrical shield encompassing the arc block, providing support for the accelerating electrode, and provided with means whereby the shield may be displaced laterally with respect to the arc block in order that the slit in the accelerating electrode may be registered with the slit in the diaphragm closing the wall of the arc chamber.
  • Figure l is a plan View of an ion source constructed according to the invention, portions thereof being broken away to show some of the features in cross section,
  • Fig. 2 is a View in side elevation with portions of the structure broken away to show certain features in cross section
  • Fig. 3 s a view in cross section along the line 3 3 of Fig. l,
  • Fig. 4 is a View in cross section along the line 4--4 of Fig. l.
  • Fig. 5 is a View in perspective wherein the accelerating electrode structure has been displaced to show certain features of construction.
  • a tank 13 disposed between the pole pieces it) and 11 of a powerful magnet (not shown).
  • the tank 13 is supported in spaced relation between the pole pieces and 11 by means of spacers i5 interposed at suitable intervals between the walls of the tank and the adjacent faces of the pole pieces l@ and 1i.
  • the tank proper terminates in a rim or header i7 to whic is bolted a terminal section i9 having a cooperating rim 23 carried on its inner end.
  • Bolts serve to clamp the headers 17 and 23 together, a vacuum seal being effected by gaskets 24 disposed between the headers.
  • in one wall of the section 19 is an outlet pipe 27 which is connected to a series of vacuum pumps (not shown) by means of which the tank is evacuated before the calutron is placed in operation.
  • the tank section 19 terminates in a rim or face plate 31 to which a heavy mounting plate 33 is secured by means of bolts 37.
  • a pair of gaskets 35 Received in recesses in the inner face of the mounting plate 33 is a pair of gaskets 35 which serve to form a vacuum seal.
  • Four hollow tubular supports 39 carry at oine end integral plugs 41 in which are received bolts 43 by means of which the supports are anchored against the inner face of the mounting plate 33.
  • the supports 39 carry plugs 47' provided with tapped holes for the reception of screws 49 which serve to clamp a plate 51 against the inner ends of the supports 39.
  • Each of the supports 39 is provided with a vent in order that the pressure Within the supports may be equal to the pressure within the tank.
  • a block 53 is secured to the plate 51 by means of a number of bolts 55 and is cut away as shown at 57 to form a charge chamber for the reception of a quantity of material to be vaporized.
  • the chamber 57 is closed at one side by means of a cover plate 59 which is secured in position after the charge has been inserted in the chamber 57.
  • One side of the block 53 is provided with a pair of bores in each of which is disposed a heater 61 of conventional type, in which a coil of high resistance wire is wound upon a core of refractory material. The function of the heaters di is to heat the block 53 and vaporize the material placed in the charge chamber 57.
  • a second block 53 is .secured to the block 53 by means of screws 65, the blocks being spaced apart by tubular f 63 is bored to receive a heater 73 similar in all respects to the heaters 61.
  • the heaters 61 are supplied by a conductori which Vpasses through a vacuum plug seal 34 inthe mounting plate 33, and the heaters 73 are served by a lead S3 also piercing the mounting plate 33 through arvacuum plug seal 84.
  • the charge chamber and the block 53 are cooled by means of a squirt tube 77 which pierces the mounting plate 33 through a vacuum plug seal 78 and is welded to the outer Vsurface of the block 53.
  • the squirt tube 77 comprises a pair of concentric tubes, the inner tube being open at its inner end so that cooling lluid may be passed in through the inner tube and back out through the outer tube. ing liquid ⁇ may be brought to the block 53.
  • a similar squirt tnbe'Sl is welded to the outer surface of the block 63 and serves to cool the arc chamber. lnasmuch as the block 53 and the block 63 each has separate heaters and squirt tubes the temperatures or the charge chamber and the arc chamber may be independently controlled.
  • Access to the are chamber 71 may be obtained by removing the cover plate S5 secured to the top of the arc chamber by screws 87.
  • the arc block 63 terminates in a tubular member e9 secured to the inner end of the block by bolts 91 and having a flange across its upper portion.
  • a thin diaphragm 93 is clamped between the tubular member 39 and the inner face of the arc block 63 to close one side of the arc chamber 71.
  • a long narrow slit 95 is formed in the diaphragm 93 and provides an exit from the arc chamber 71.
  • a metal shield or cylinder 101 Surrounding the arc block and its supporting structure is a metal shield or cylinder 101 having at its outer end a rim or flange 103 welded or otherwise suitably secured to it and providing means for anchoring the shield 1701 to the inner face of the mounting plate 33. Screws 105 pass through apertures in the rim 103 and are received in holes tapped in the inner face of the plate 33.
  • the shield 101 At its inner end the shield 101 carries a circular ange 107 which serves to stilen the shield 101 as well as to provide a base upon which are mounted four stand-olf insulators 129 of conventional ceramic construction.
  • a block 111 Secured to the outer surface of the ange 107 and extending into the interior of the shield 101 is a block 111 having an insulating insert 113 formed in two parts between which'are clamped a pair of conductors 109 which extend along the interior of the shield 101 and through Vacuum seals 123 in the mounting plate 33.
  • a Bakelite block 127 Outside the plate33 and adjacent thereto is a Bakelite block 127 provided in its upper surface with a pair of parallel grooves in which the cathode leads 109 lie.
  • a pair of metal caprblocks are screwed to the Bakelite block 127 to clamp the leads 109 in place.
  • the block 111 is secured to the flange 107 by means of a pair of screws 117.
  • the .innerV end of Yeach of the conductors 109 carries a clamp block 121 in which are receivedthe legs of a substantially U-shaped tilarnentaryrcathode 119.
  • the clamp blocks 121 serve to support the filament 119 in a plane parallel to the direction of the magnetic l'luX between the pole pieces 10 .and 11, the direction of the ux being indicated by the arrow 115.
  • the filament 119 extends through an aperture formed in the cover plate 85 and into the interior of the arc chamber 71, and in the assembly of the device the axis of the ilament 119 is aligned with the inner face of the slotted diaphragm 93.
  • the iilamrent 119 maybe of tungsten or any of the materials cornmonly used for electron emissive cathodes.
  • an arc or stream of electrons ows from the lilament 1119 along the inner face of thediaphragm 93
  • the slit formed in the diaphragm 93 is aligned with the pathof the are and is so dimensioned that substantially all material leaving the arc chamber 71 through the slit 91 must lirst traverse the arc.
  • an accelerating electrode is mounted adjacent the slit 95, and as shown herein, comprises a second diaphragm 139 having a centrally located elongated slit and pinned to the end of a sleeve 133 having an outwardly extending radial ange 135 mounted in a circular aperture formed in a rectangular metal plate -131 which 'is carried upon the four stand-oit insulators 129 previously described as mounted on the flange 107.
  • the diaphragm 139 is thus received within a re-entrant portion of the arc block 63.
  • a metal'block 137 is welded to the plate 131 and provided with a tapped hole for the reception of a threaded conductor 159 adapted to be inserted through a wall of the tank section 19.
  • a tank section 19 is cut away to receive a glass window 141 which is provided with an aperture through which extends a brass bushing 143 having an external thread on its inner portion.
  • a washer 147 surrounding the bushing 143 bears upon a ring gasket 151 disposed against the inner surface of the glass window 141.
  • a retaining ring 149 isV internally threaded to engage the threads on the bushing 143.
  • the bushing 143 has an integral anged head which bears against a ring gasket disposed against the outer surface of the glass window 141.
  • gaskets 145 and 151 are compressed to form a vacu.
  • a ring is riveted to the head of the bushing 143 and clamps in position a rubber gasket 153 having less diameter than the diameter of the aperture in the bushing 143.
  • the electrode 159 is inserted through the aperture of the bushing 143, vthe gasket 153 bearing against Vthe vperiphery of the electrode 159 and forming a vacuum seal.
  • the electrode 159 is inserted in the rtank and screwed into the block 137.
  • a conductor 161 is connected to the outer end of the electrode 159 and is connected to a suitable source of pov tential.
  • the flange 107 is provided with integral blocks 171 through which are threaded long machine screws 175 one of which bears against' each or vaporizing .chamber 57 after which the side ⁇ plate Y 59 is screwed in place.
  • the mounting plate 33 is then secured to the face plate 31 so that the ion beam sourceV is mounted within the tank section 19.
  • the electrode 159 is screwed into the block 137.
  • the tank is then evacuated by means of vacuum pumps connected to the manifold 27 and the ⁇ magnet is energized.
  • the heaters 61 are energized to heat the block 53 and to cause the material therein to become vaporized.
  • the Vvapor formed vin the charge chamber 57 travels through the tube 69 into the arc chamber, the diierence in pressure between the two chambers serving to draw vapor in a constant stream from the chamber 57 into the arc chamber 71.
  • the filament leads 109 are connected to a suitable source of potential for heating the lament 119 which thereupon becomes electron emissive.
  • the arc block 63 is rendered electrically positive with respect to the iilament 119 whereupon an arc discharge is struck from the lament 119 across the inner face of the diaphragm 93 to the bottom of the arc chamber 71.
  • the electrode 159 is connected to a source of potential serving to render the accelerating electrode or diaphragm 93 highly negative with respect to the arc block 63.
  • the arc in the chamber 71 ionizes the vapor coming from the chamber 57, forming, in the case of uranium tetrachloride, negative chlorine ions and positive ions of U234, U235, and U233.
  • the positive ions are attracted by the negative accelerating electrode and are drawn from the chamber 71 at high velocity through the slit 9S and pass as a beam or ribbon through the slit in the diaphragm 139.
  • the beam of positive ions thus produced traverses the tank 13 in a curved path, the magnetic iiux between the pole pieces and 11 serving to bend the beam into a curve.
  • the heavier U238 ions are slightly less affected by the magnetic ilux, due to their heavier mass, than are the lighter ions of D234 and U235. Consequently, as the ions leave the source and progress along the path of the beam, the heavier ions drift to the outer periphery of the curved path, whereas the lighter ions concentrate along the inner periphery of the curve.
  • collectors are disposed within the tank a suitable distance from the source and so arranged that the heavier ions of U238 are collected separately from the lighter ions of U234 and U235. 'Ihe collecting mechanism is not shown herein, since it forms no part of the present invention.
  • a calutron comprising a vacuum vessel having a wall, means for establishing a magnetic lield, structure fixed on said Wall for forming an arc chamber with an exit slit, means for supplying gas to be ionized to said arc chamber, arc generating means mounted on said structure and associated with said arc chamber and said exit slit, a shield encompassing said structure mounted on said wall, insulating means mounted on said shield, accelerating means mounted on said insulating means in operative relationship with said exit slit, oppositely disposed screws received in said shield and bearing on said structure for displacing said shield with respect to said structure and aligning said slit and said accelerating means. and a collector unit disposed in said vessel for intercepting said accelerated ions.
  • a calutron comprising a vacuum vessel having a wall, means for establishing a magnetic field, structure xed on said Wall for forming an arc chamber with an exit slit, means for supplying gas to be ionized to said arc chamber, arc generating means mounted on said structure and associated with said arc chamber and said exit slit, a shield encompassing said structure mounted on said Wall, insulating means mounted on said shield, accelerating means mounted on said insulating means in operative relationship with said exit slit, means for adjustably displacing said shield with respect to said exit slit for aligning said eXit slit and said accelerating means, and a collector unit disposed in said vessel for intercepting said accelerated ions.
  • a calutron comprising a vacuum vessel having a wall, means for establishing a magnetic eld through said vessel, an ion source mechanism fixed on said wall, a cylindrical shield encompassing said mechanism and mounted on said wall, an accelerator mounted on said shield in operative relationship with said mechanism, means for adjustably displacing said shield with respect to said mechanism, and means disposed within said vessel for intercepting said accelerated ions.
  • a calutron comprising a vacuum vessel having a wall, means for establishing a magnetic eld through said vessel, an ion source mechanism mounted on said wall, a shield encompassing said mechanism mounted on said wall, insulating means mounted on said shield, an accelerator mounted on said insulating means in operative relationship with said mechanism, means for adjustably displacing said shield with respect to said mechanism, and means disposed within said vessel for intercepting said accelerated ions.
  • An ion beam source for a calutron comprising an arc block having a chamber formed therein, a diaphragm closing one side of said chamber and provided With an elongated slit, means for supplying gas to be ionized to said chamber, arc generating means mounted on said arc block and associated with said chamber and said slit, a tubular member secured to said block and surrounding said diaphragm, a sleeve mounted within said tubular member, a second diaphragm carried on said sleeve and provided with an elongated slit, said second diaphragm being disposed closely adjacent said rst diaphragm, electrical means for maintaing said second diaphragm negative with respect to said first diaphragm, means for adjustably displacing said second diaphragm with respect to said first diaphragm for aligning the slits therein, and means for establishing a magnetic field in the direction of said arc.
  • An ion beam source for a calutron comprising an are block having a chamber formed therein, a diaphragm closing one side of said chamber and providing an elongated slit, means for supplying gas to be ionized to said chamber, arc generating means mounted on said arc block and associated with said chamber and said slit, a tubular member secured to said block and surrounding said diaphragm, a shield encompassing said arc block mounted on one end of said arc block, insulators mounted on the free end of said shield, a sleeve mounted on said insulators within said tubular member, a second diaphragm carried on said sleeve and provided with an elongated slit, said second diaphragm being disposed closely adjacent said rst diaphragm, electrical means for maintaining said second diaphragm negative with respect to said iirst diaphragm, oppositely disposed screws received in said shield and bearing on said arc block for displac

Description

Allg 16, 1955 J. G. BAcKUs ETAL 2,715,683
10N SOURCE FOR A CALUTRON Aug. 16, 1955 1. G. BAcKUs ETAx. 2,715,583
ION SOURCE FOR A CALUTRON Filed Feb. 16, 1945 4 Sheets-Sheet 2 Aug. 16, 1955 J. G. BACKUS ETAL 2,715,583
10N SOURCE FOR A CALUTRON Filed Feb. 16, 1945 4 Sheets-Sheet 3 Aug. 16, 1955 J. G. BAcKUs ErAx.
ION SOURCE FOR A CALUTRON 4 Sheets-Sheet 4 Filed Feb. 16, 1945 United States Patent O1 ioni sonnen non a catUrnoN John G. Backus and Bernard Peters, Berkeley, Calif., assignors to the United States oi' America as represented by the United States Atomic Energy Commission Application February 16, 134:3, Serial No. 573,289
6 Ciaims. (Cl. 25u-41.9)
The present invention relates to the art of separating a polyisotope into a plurality of substantially mono-isotopic masses. More particularly, my invention relates to a calutron, a device wherein a polyisotopic substance is vaporized and then ionized under conditions causing a beam of positive ions to traverse an evacuated tank disposed between the pole pieces of a powerful magnet. The action of the magnetic flux causes the beam of ions to follow a curved path; ions of heavier isotopes tend to concentrate along the outer periphery of the curve, and ions of lighter isotopes follow the inner periphery of the curve. By placing a suitable collector in the path of the beam, preferably 180 from its source, it is possible to segregate and collect masses in which the distribution of isotopes has been radically changed or in which isotopes are substantially completely separated. For eX- ample, a calutron is useful for separating naturally occurring uranium containing U235 and U23S into two masses of which one is enriched with respect to U235 and the other is correspondingly impoverished.
It is with the mechanism for producing the beam of ions that this invention particularly deals. lt has been found that a satisfactory device for generating a beam of ions may comprise a charge chamber in which a charge of material to be vaporized is heated, and an arc chamber having a lamentary cathode suitably positioned to strike an arc across the chamber and ionize the molecules of the vaporized polyisotope. in one wall of the arc chamber there is an elongated exit slit, and an accelerating electrode maintained at a highly negative potential is disposed in advance of the exit slit. The function of the latter electrode is to attract the positive ions formed in the arc chamber and draw them through the exit slit with considerable velocity in the form of a narrow ribbon or beam which traverses the evacuated tank in a path normal to the direction of the ux in the magnetic eld formed between pole pieces of the magnet. A complete description of a calutron and its theory of operation is to be found in the copending application of Ernest O. Lawrence, Serial No. 557,784, filed October 9, 1944.
One object of the invention is to produce in a calutron a more stable beam of positive ions.
A further object of the invention is to provide a simple and compact ion source for a calutron.
Another object of the invention is to provide an ion source for a calutron in which a large percentage of vaporized material is ionized and formed in a beam.
An important feature of the invention resides in the combination of a diaphragm closing one side of the arc chamber and having an elongated slit disposed in register with a similar slit in a second diaphragm mounted closely adjacent the iirst diaphragm and maintained at a highly negative potential with respect thereto.
Another feature of the invention resides in disposing the accelerating electrode adjacent the bottom of a cupshaped depression formed in one Wall of the arc block. This feature has the advantage of preventing the random escape of ions from the arc chamber and increases the ice efficiency of the ion source in that substantially all of the ions formed in the arc chamber are drawn into the beam.
A further feature of the invention resides in a cylindrical shield encompassing the arc block, providing support for the accelerating electrode, and provided with means whereby the shield may be displaced laterally with respect to the arc block in order that the slit in the accelerating electrode may be registered with the slit in the diaphragm closing the wall of the arc chamber.
ri`hese and other objects and features of the invention will be more readily understood and appreciated from the following detailed description of a preferred embodiment thereof selected for purposes of illustration and shown in the accompanying drawings, in which:
Figure l is a plan View of an ion source constructed according to the invention, portions thereof being broken away to show some of the features in cross section,
Fig. 2 is a View in side elevation with portions of the structure broken away to show certain features in cross section,
Fig. 3 s a view in cross section along the line 3 3 of Fig. l,
Fig. 4 is a View in cross section along the line 4--4 of Fig. l, and
Fig. 5 is a View in perspective wherein the accelerating electrode structure has been displaced to show certain features of construction.
Referring particularly to Fig. 2, there is shown a tank 13 disposed between the pole pieces it) and 11 of a powerful magnet (not shown). The tank 13 is supported in spaced relation between the pole pieces and 11 by means of spacers i5 interposed at suitable intervals between the walls of the tank and the adjacent faces of the pole pieces l@ and 1i. The tank proper terminates in a rim or header i7 to whic is bolted a terminal section i9 having a cooperating rim 23 carried on its inner end. Bolts serve to clamp the headers 17 and 23 together, a vacuum seal being effected by gaskets 24 disposed between the headers. in one wall of the section 19 is an outlet pipe 27 which is connected to a series of vacuum pumps (not shown) by means of which the tank is evacuated before the calutron is placed in operation.
At its outer end the tank section 19 terminates in a rim or face plate 31 to which a heavy mounting plate 33 is secured by means of bolts 37. Received in recesses in the inner face of the mounting plate 33 is a pair of gaskets 35 which serve to form a vacuum seal. Four hollow tubular supports 39 carry at oine end integral plugs 41 in which are received bolts 43 by means of which the supports are anchored against the inner face of the mounting plate 33. At their inner ends, the supports 39 carry plugs 47' provided with tapped holes for the reception of screws 49 which serve to clamp a plate 51 against the inner ends of the supports 39. Each of the supports 39 is provided with a vent in order that the pressure Within the supports may be equal to the pressure within the tank.
A block 53 is secured to the plate 51 by means of a number of bolts 55 and is cut away as shown at 57 to form a charge chamber for the reception of a quantity of material to be vaporized. The chamber 57 is closed at one side by means of a cover plate 59 which is secured in position after the charge has been inserted in the chamber 57. One side of the block 53 is provided with a pair of bores in each of which is disposed a heater 61 of conventional type, in which a coil of high resistance wire is wound upon a core of refractory material. The function of the heaters di is to heat the block 53 and vaporize the material placed in the charge chamber 57.
A second block 53 is .secured to the block 53 by means of screws 65, the blocks being spaced apart by tubular f 63 is bored to receive a heater 73 similar in all respects to the heaters 61. The heaters 61 are supplied by a conductori which Vpasses through a vacuum plug seal 34 inthe mounting plate 33, and the heaters 73 are served by a lead S3 also piercing the mounting plate 33 through arvacuum plug seal 84.
The charge chamber and the block 53 are cooled by means of a squirt tube 77 which pierces the mounting plate 33 through a vacuum plug seal 78 and is welded to the outer Vsurface of the block 53. The squirt tube 77 comprises a pair of concentric tubes, the inner tube being open at its inner end so that cooling lluid may be passed in through the inner tube and back out through the outer tube. ing liquid `may be brought to the block 53. A similar squirt tnbe'Sl is welded to the outer surface of the block 63 and serves to cool the arc chamber. lnasmuch as the block 53 and the block 63 each has separate heaters and squirt tubes the temperatures or the charge chamber and the arc chamber may be independently controlled.
i Access to the are chamber 71 may be obtained by removing the cover plate S5 secured to the top of the arc chamber by screws 87. The arc block 63 terminates in a tubular member e9 secured to the inner end of the block by bolts 91 and having a flange across its upper portion. A thin diaphragm 93 is clamped between the tubular member 39 and the inner face of the arc block 63 to close one side of the arc chamber 71. A long narrow slit 95 is formed in the diaphragm 93 and provides an exit from the arc chamber 71.
Surrounding the arc block and its supporting structure is a metal shield or cylinder 101 having at its outer end a rim or flange 103 welded or otherwise suitably secured to it and providing means for anchoring the shield 1701 to the inner face of the mounting plate 33. Screws 105 pass through apertures in the rim 103 and are received in holes tapped in the inner face of the plate 33. At its inner end the shield 101 carries a circular ange 107 which serves to stilen the shield 101 as well as to provide a base upon which are mounted four stand-olf insulators 129 of conventional ceramic construction.
Secured to the outer surface of the ange 107 and extending into the interior of the shield 101 is a block 111 having an insulating insert 113 formed in two parts between which'are clamped a pair of conductors 109 which extend along the interior of the shield 101 and through Vacuum seals 123 in the mounting plate 33. Outside the plate33 and adjacent thereto is a Bakelite block 127 provided in its upper surface with a pair of parallel grooves in which the cathode leads 109 lie. A pair of metal caprblocks are screwed to the Bakelite block 127 to clamp the leads 109 in place. The block 111 is secured to the flange 107 by means of a pair of screws 117. The .innerV end of Yeach of the conductors 109 carries a clamp block 121 in which are receivedthe legs of a substantially U-shaped tilarnentaryrcathode 119. The clamp blocks 121 serve to support the filament 119 in a plane parallel to the direction of the magnetic l'luX between the pole pieces 10 .and 11, the direction of the ux being indicated by the arrow 115. The filament 119 extends through an aperture formed in the cover plate 85 and into the interior of the arc chamber 71, and in the assembly of the device the axis of the ilament 119 is aligned with the inner face of the slotted diaphragm 93. The iilamrent 119 maybe of tungsten or any of the materials cornmonly used for electron emissive cathodes. When the filament is rendered electrically negative with respect to the Iarc: block 63, an arc or stream of electrons ows from the lilament 1119 along the inner face of thediaphragm 93 By this means, a continuous how or coolto the bottom of the arc chamber 71. Although the en-Y the arc assumes a pencil shape because the powerfulV magnetic ux collimates the electron stream. The slit formed in the diaphragm 93 is aligned with the pathof the are and is so dimensioned that substantially all material leaving the arc chamber 71 through the slit 91 must lirst traverse the arc.
In order to form a beam of positive ions an accelerating electrode is mounted adjacent the slit 95, and as shown herein, comprises a second diaphragm 139 having a centrally located elongated slit and pinned to the end of a sleeve 133 having an outwardly extending radial ange 135 mounted in a circular aperture formed in a rectangular metal plate -131 which 'is carried upon the four stand-oit insulators 129 previously described as mounted on the flange 107. The diaphragm 139 is thus received within a re-entrant portion of the arc block 63.
In order to render the accelerating electrode 139 electrically negative with respect to the arc block 63 a metal'block 137 is welded to the plate 131 and provided with a tapped hole for the reception of a threaded conductor 159 adapted to be inserted through a wall of the tank section 19.
To provide a mounting for the electrode 159 a portion of the wall ol` a tank section 19 is cut away to receive a glass window 141 which is provided with an aperture through which extends a brass bushing 143 having an external thread on its inner portion. A washer 147 surrounding the bushing 143 bears upon a ring gasket 151 disposed against the inner surface of the glass window 141. A retaining ring 149 isV internally threaded to engage the threads on the bushing 143. The bushing 143 has an integral anged head which bears against a ring gasket disposed against the outer surface of the glass window 141. When the retaining ring 149 is tightened,
the gaskets 145 and 151 are compressed to form a vacu.
um seal. A ring is riveted to the head of the bushing 143 and clamps in position a rubber gasket 153 having less diameter than the diameter of the aperture in the bushing 143. The electrode 159 is inserted through the aperture of the bushing 143, vthe gasket 153 bearing against Vthe vperiphery of the electrode 159 and forming a vacuum seal. Y
After the` arc block, the filament, and the accelerating electrode vhave been assembled on the mounting plate 33 and secured in place within the tank, the electrode 159 is inserted in the rtank and screwed into the block 137. A conductor 161 is connected to the outer end of the electrode 159 and is connected to a suitable source of pov tential.
In order Ato provide an adjustment between .the diaphragms 93 and 139 in order that the slits therein may be brought into register, the flange 107 is provided with integral blocks 171 through which are threaded long machine screws 175 one of which bears against' each or vaporizing .chamber 57 after which the side `plate Y 59 is screwed in place. The mounting plate 33 is then secured to the face plate 31 so that the ion beam sourceV is mounted within the tank section 19. The electrode 159 is screwed into the block 137. The tank is then evacuated by means of vacuum pumps connected to the manifold 27 and the `magnet is energized. vThe heaters 61 are energized to heat the block 53 and to cause the material therein to become vaporized. The Vvapor formed vin the charge chamber 57 travels through the tube 69 into the arc chamber, the diierence in pressure between the two chambers serving to draw vapor in a constant stream from the chamber 57 into the arc chamber 71. The filament leads 109 are connected to a suitable source of potential for heating the lament 119 which thereupon becomes electron emissive. By suitable connections (not shown) the arc block 63 is rendered electrically positive with respect to the iilament 119 whereupon an arc discharge is struck from the lament 119 across the inner face of the diaphragm 93 to the bottom of the arc chamber 71. The electrode 159 is connected to a source of potential serving to render the accelerating electrode or diaphragm 93 highly negative with respect to the arc block 63.
The arc in the chamber 71 ionizes the vapor coming from the chamber 57, forming, in the case of uranium tetrachloride, negative chlorine ions and positive ions of U234, U235, and U233. The positive ions are attracted by the negative accelerating electrode and are drawn from the chamber 71 at high velocity through the slit 9S and pass as a beam or ribbon through the slit in the diaphragm 139. As previously explained the beam of positive ions thus produced traverses the tank 13 in a curved path, the magnetic iiux between the pole pieces and 11 serving to bend the beam into a curve. The heavier U238 ions are slightly less affected by the magnetic ilux, due to their heavier mass, than are the lighter ions of D234 and U235. Consequently, as the ions leave the source and progress along the path of the beam, the heavier ions drift to the outer periphery of the curved path, whereas the lighter ions concentrate along the inner periphery of the curve. As explained in the copending application of Ernest O. Lawrence, collectors are disposed within the tank a suitable distance from the source and so arranged that the heavier ions of U238 are collected separately from the lighter ions of U234 and U235. 'Ihe collecting mechanism is not shown herein, since it forms no part of the present invention.
While one preferred embodiment of the invention has been described herein, it will be evident to those skilled in the art that the invention is not limited to the details of the apparatus shown and described. An infinite number of variations might be eiected in the source discussed without departing from the spirit of the invention as deiined in the appended claims.
What is claimed is:
l. A calutron comprising a vacuum vessel having a wall, means for establishing a magnetic lield, structure fixed on said Wall for forming an arc chamber with an exit slit, means for supplying gas to be ionized to said arc chamber, arc generating means mounted on said structure and associated with said arc chamber and said exit slit, a shield encompassing said structure mounted on said wall, insulating means mounted on said shield, accelerating means mounted on said insulating means in operative relationship with said exit slit, oppositely disposed screws received in said shield and bearing on said structure for displacing said shield with respect to said structure and aligning said slit and said accelerating means. and a collector unit disposed in said vessel for intercepting said accelerated ions.
2. A calutron comprising a vacuum vessel having a wall, means for establishing a magnetic field, structure xed on said Wall for forming an arc chamber with an exit slit, means for supplying gas to be ionized to said arc chamber, arc generating means mounted on said structure and associated with said arc chamber and said exit slit, a shield encompassing said structure mounted on said Wall, insulating means mounted on said shield, accelerating means mounted on said insulating means in operative relationship with said exit slit, means for adjustably displacing said shield with respect to said exit slit for aligning said eXit slit and said accelerating means, and a collector unit disposed in said vessel for intercepting said accelerated ions.
3. A calutron comprising a vacuum vessel having a wall, means for establishing a magnetic eld through said vessel, an ion source mechanism fixed on said wall, a cylindrical shield encompassing said mechanism and mounted on said wall, an accelerator mounted on said shield in operative relationship with said mechanism, means for adjustably displacing said shield with respect to said mechanism, and means disposed within said vessel for intercepting said accelerated ions.
4. A calutron comprising a vacuum vessel having a wall, means for establishing a magnetic eld through said vessel, an ion source mechanism mounted on said wall, a shield encompassing said mechanism mounted on said wall, insulating means mounted on said shield, an accelerator mounted on said insulating means in operative relationship with said mechanism, means for adjustably displacing said shield with respect to said mechanism, and means disposed within said vessel for intercepting said accelerated ions.
5. An ion beam source for a calutron comprising an arc block having a chamber formed therein, a diaphragm closing one side of said chamber and provided With an elongated slit, means for supplying gas to be ionized to said chamber, arc generating means mounted on said arc block and associated with said chamber and said slit, a tubular member secured to said block and surrounding said diaphragm, a sleeve mounted within said tubular member, a second diaphragm carried on said sleeve and provided with an elongated slit, said second diaphragm being disposed closely adjacent said rst diaphragm, electrical means for maintaing said second diaphragm negative with respect to said first diaphragm, means for adjustably displacing said second diaphragm with respect to said first diaphragm for aligning the slits therein, and means for establishing a magnetic field in the direction of said arc.
6. An ion beam source for a calutron comprising an are block having a chamber formed therein, a diaphragm closing one side of said chamber and providing an elongated slit, means for supplying gas to be ionized to said chamber, arc generating means mounted on said arc block and associated with said chamber and said slit, a tubular member secured to said block and surrounding said diaphragm, a shield encompassing said arc block mounted on one end of said arc block, insulators mounted on the free end of said shield, a sleeve mounted on said insulators within said tubular member, a second diaphragm carried on said sleeve and provided with an elongated slit, said second diaphragm being disposed closely adjacent said rst diaphragm, electrical means for maintaining said second diaphragm negative with respect to said iirst diaphragm, oppositely disposed screws received in said shield and bearing on said arc block for displacing said shield with respect to said structure and aligning said slits, and means for establishing a magnetic iield in the direction of said arc.
References Cited in the file of this patent UNITED STATES PATENTS 2,221,467 Bleakncy Nov. 12, 1940 2,341,551 Hoover Feb. 15, 1944 2,374,205 Hoskins Apr. 24, 1945 2,376,877 Langmuir May 29, 1945

Claims (1)

1. A CALUTRON COMPRISING A VACUUM VESSEL HAVING A WALL, MEANS FOR ESTABLISHING A MAGNETIC FIELD, STRUCTURE FIXED ON SAID WALL FOR FORMING AN ARC CHAMBER WITH AN EXIT SLIT, MEANS FOR SUPPLYING GAS TO THE IONIZED TO SAID ARC CHAMBER, ARC GENERATING MEANS MOUNTED ON SAID STRUCTURE AND ASSOCIATED WITH SAID ARC CHAMBER AND SAID EXIT SLIT, A SHIELD ENCOMPASSING SAID STRUCTURE MOUNTED ON SAID WALL, INSULATING MEANS MOUNTED ON SAID SHIELD, ACCELERATING MEANS MOUNTED ON SAID INSULATING MEANS IN OPERATIVE RELATIONSHIP WITH SAID EXIT SLIT, OPPOSITELY DISPOSED SCREWS RECEIVED IN SAID SHIELD AND BEARING ON SAID STRUCTURE FOR DISPLACING SAID SHIELD WITH RESPECT TO SAID STRUCTURE AND ALIGNING SAID SLIT AND SAID ACCELERATING MEANS, AND A COLLECTOR UNIT DISPOSED IN SAID VESSEL FOR INTERCEPTING SAID ACCELERATED IONS.
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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2975277A (en) * 1955-05-10 1961-03-14 Vakutronik Veb Ion source
US3115575A (en) * 1961-10-31 1963-12-24 Jr William A Bell Ion-producing mechanism for calutrons

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2221467A (en) * 1938-12-27 1940-11-12 Research Corp Focusing and separation of charged particles
US2341551A (en) * 1940-05-04 1944-02-15 Cons Eng Corp Mass spectrometer
US2374205A (en) * 1943-07-03 1945-04-24 Cons Eng Corp Mass spectrometry
US2376877A (en) * 1942-05-25 1945-05-29 Cons Eng Corp Mass spectrometry

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2221467A (en) * 1938-12-27 1940-11-12 Research Corp Focusing and separation of charged particles
US2341551A (en) * 1940-05-04 1944-02-15 Cons Eng Corp Mass spectrometer
US2376877A (en) * 1942-05-25 1945-05-29 Cons Eng Corp Mass spectrometry
US2374205A (en) * 1943-07-03 1945-04-24 Cons Eng Corp Mass spectrometry

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2975277A (en) * 1955-05-10 1961-03-14 Vakutronik Veb Ion source
US3115575A (en) * 1961-10-31 1963-12-24 Jr William A Bell Ion-producing mechanism for calutrons

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