US2354122A - Vacuum tube - Google Patents

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Publication number
US2354122A
US2354122A US439345A US43934542A US2354122A US 2354122 A US2354122 A US 2354122A US 439345 A US439345 A US 439345A US 43934542 A US43934542 A US 43934542A US 2354122 A US2354122 A US 2354122A
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tube
molecules
slit
vacuum tube
curved
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Expired - Lifetime
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US439345A
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Jr John A Hipple
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CBS Corp
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Westinghouse Electric and Manufacturing Co
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Priority to US439345A priority Critical patent/US2354122A/en
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J29/00Details of cathode-ray tubes or of electron-beam tubes of the types covered by group H01J31/00
    • H01J29/02Electrodes; Screens; Mounting, supporting, spacing or insulating thereof
    • H01J29/06Screens for shielding; Masks interposed in the electron stream

Definitions

  • My invention relates to vacuum tubes and in particular relates to an arrangement for providing an electrostatic shield adjacent the interior surface of portions of vacuum tube structures.
  • One object of my invention is accordingly to provide a convenient and satisfactory method of forming a conductive coating to lie closely adja cent the interior of an insulating tube.
  • Another object of my invention is to provide an electrostatic shield of a novel type for the interior of an insulatingtube.
  • Still another object of my invention is to provide a metallic lining for the interior of a curved tube of insulating material.
  • Figure 1 is a view partly in elevation and partly in section of a vacuum tube embodying a shielding device according to my invention.
  • Figs. 2 to 5 are detailed views used in illustrating the precise structure of the shielding device according to my invention; Fig. 2 being an elevational view from one side; Fig. 3 an edge view; Fig. 4 an elevational view from the opposite side of the shielding device while in the course of construction; and Fig. 5 an enlarged section on the line VV in Fig. 1. 7
  • a cylindrical tube I which may conveniently be made of glass has its axis bent in the arc of a circle and is provided with electrode chambers 2 and 3 at its opposite ends.
  • I apply it to a mass spectrometer such as has been referred to above.
  • This consists of a cathode chamber 4 containing a suitable thermionic filament 5 or other source of electrons and having a slit 6 in its wall through which such electrons may travel to the exterior of the chamber l.
  • a hollow anode 1 attracts electrons emerging through the slit 5 these electrons being accelerated by an electrical field due to a difference of potential maintained between the chamber 4 and anode l.
  • the anode l is provided with an aperture or slit 8 aligned with the aperture 6 in chamber 4 and another electrode 9 which has a horizontal base and a pair of walls normal thereto, each such wall being provided with an aperture or slit l0 aligned with the slits 6 and 8.
  • An electrode l I nearly fills the space between the walls of electrode 9, thus forming a small box through which electrons attracted by anode I pass.
  • the electrode 9 is maintained at a potential a volt or so lower than the electrode l l and so accelerates positive gas ions formed in this box downward toward an aperture l2 in the floor of this box.
  • the tube l is provided with a metalshield or liner I3 which will be described in more detail below, and the end of liner I3 projecting into chamber 2 is capped with a flanged sleeve I4 leaving a slit I5 aligned with slit I2.
  • the space between the electrodes 9 and II contains molecules of gas which it is desired to segregate from each other or otherwise test. Electrons emanating through the slit 8 ionize by impact the molecules just mentioned and a negative potential of about 1000 volts on the electrode gives them an acceleration downward. Some of these molecules pass through the slit I5 into the main body of the tube I.
  • the tube I is maintained at a considerable d gree of vacuum, for example, l mm. of mercury by a pump connected to a lead-off IS.
  • the chamber 3 contains a metallic diaphragm I! having an aperture slit I8, a second metal diaphragm I9 containing a slit 2
  • the tube thus arranged is placed between the jaws of an electromagnet which sets up a field of nearly normal intensity perpendicular to the plane of Fig. 1.
  • the molecules emerging with a considerable velocity through the slit I pass into this magnetic field which is made of as constant an intensity as possible throughout the length of the curved portion of the tube I.
  • This magnetic field causes the molecules to follow curved paths, all the molecules of the same molecular weight having a path of the same radius, but these radii being different for different groups of molecules which have different molecular Weights.
  • the tube I is provided with a liner I3 which is made up in the following way.
  • a piece of metal ribbon for example, a Nichrome V ribbon, 2 mils thick by A" wide and preferably unannealed, is cut into numerous pieces 3I each having a length slightly greater than the internal perimeter of tube I.
  • a strap 32 which mat be of Nichrome V wide by 3 mils thick is welded to the successive pieces 3
  • the pieces 3I will, for convenience, hereinafter be called scales.
  • the scales 3I are each slightly reduced in width near the point to which it is welded to the strap.
  • the scales H are bent one by one and slipped into a straight glass tube so that they line its walls somewhat as shown in Fig. 5.
  • the natural spring of the metal ribbon tends to force the scales against the surrounding glass tube.
  • the straight glass tube is of the same internal diameter as the cylindrical portion of the tube I. Before the end chambers of the tube I are fused into place on the latter the straight glass tube is placed in alignment with one end of the cylindrical portion of tube I, a wire attached to the liner being fed through the tube I and out its opposite end. By drawing on the wire just mentioned, it is possible to draw the liner out of the straight glass tube and into the curved cylindrical portion of tube I to form a shield therein.
  • Holes 33 are preferably provided in advance in the position of the liner which will lie opposite the pump lead I5.
  • a vacuum tube comprising a wall portion of insulating material in the form of a cylinder and a metallic lining for said wall portion comprising a flexible metal strap having fastened thereon a series of overlapping metal scales.
  • a vacuum tube comprising a wall portion of insulating material in the form of a cylinder and a metallic lining for said Wall portion comprising a flexible metal strap carrying a series of overlapping scales of elastic metal.
  • a vacuum tube comprising a wall portion of insulating material in the form of a cylinder having a curved axis and a metallic lining for said wall portion comprising a flexible metal strap having fastened thereon a series of overlapping metal scales.

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  • Other Investigation Or Analysis Of Materials By Electrical Means (AREA)
  • Particle Accelerators (AREA)

Description

Jufi gr 18, 1944. J..A. HIPPLE, JR
VACUUM TUBE Filed April 17, 1942 lNVN John A. Hzpple, J2?
WITNESSES:
ATTORN Patented July 18, 1944 VACUUM TUBE John A I-lipple, Jr., Forest Hills, Pa., assignor to Westinghouse Electric & Manufacturing Company, East Pittsburgh, Pa., a corporation of Pennsylvania Application April 17, 1942, Serial No. 439,345
3 Claims. (Cl. 25027.5)
My invention relates to vacuum tubes and in particular relates to an arrangement for providing an electrostatic shield adjacent the interior surface of portions of vacuum tube structures.
For many purposes it is desirable to provide a path for electrons or other charged particles travelling in the interior of the vacuum tubes which shall be shielded from the effects of electrical fields set up in the neighborhood of the tube walls. Thus, for example, mass spectrometers are used in which single molecules of various materials are given electric charges and are then accelerated to considerable velocities to move through a magnetic field. The latter causes the charged particles to follow a curved path, the radius of curvature of which is proportional to the square root of the molecular mass. In this way molecules of different gases, or even isotopes of the same gas, which have different masses are caused to move in paths of different radius, and this makes it possible to segregate from a mixture of different molecules anyone set having the same mass. Economy of size in the vacuum tube employed for this purpose makes it desirable, to
make it in the form of a curved tube of length considerable relative to its diameter. But, however, if the charged molecules were allowed to be acted upon by stray electrical fields emanating from objects in the vicinity of the tube they would be deflected from the curve in which molecules of .a particular mass would otherwise be caused to traverse by the magnetic field and confusion in the observation and segregation of the charged molecules would result. The action of the molecules of such stray electrical fields emanating from objects in the neighborhood of the tube can be substantially eliminated if the curved tube along the action of which the molecules are to travel is given walls having a substantially electrical conductivity. While it is possible to make such curved tubes to form portions of a high vacuum-tight enclosure, difficulty is nevertheless met with from problems from gas occlusion and other causes which make it desirable to employ glass tubes in place of metal. However, the problem is then encountered of coating the interior of the glass wall with some electrical conductor and this problem has been found by experience one of considerable difliculty. A solution which I have found to prove extremely satisfactory is to provide a metallic ribbon having overlapping turns which can be slipped into place as to form a conductive lining for the interior of the tube wall.-
One object of my invention is accordingly to provide a convenient and satisfactory method of forming a conductive coating to lie closely adja cent the interior of an insulating tube.
Another object of my invention is to provide an electrostatic shield of a novel type for the interior of an insulatingtube.
Still another object of my invention is to provide a metallic lining for the interior of a curved tube of insulating material.
Other objects of my invention will become apparent when reading the accompanying description when taken in connection with the drawing in which Figure 1 is a view partly in elevation and partly in section of a vacuum tube embodying a shielding device according to my invention.
Figs. 2 to 5 are detailed views used in illustrating the precise structure of the shielding device according to my invention; Fig. 2 being an elevational view from one side; Fig. 3 an edge view; Fig. 4 an elevational view from the opposite side of the shielding device while in the course of construction; and Fig. 5 an enlarged section on the line VV in Fig. 1. 7
Referring in detail to Figure 1, a cylindrical tube I which may conveniently be made of glass has its axis bent in the arc of a circle and is provided with electrode chambers 2 and 3 at its opposite ends. For purposes of illustration of my invention I apply it to a mass spectrometer such as has been referred to above. This consists of a cathode chamber 4 containing a suitable thermionic filament 5 or other source of electrons and having a slit 6 in its wall through which such electrons may travel to the exterior of the chamber l. A hollow anode 1 attracts electrons emerging through the slit 5 these electrons being accelerated by an electrical field due to a difference of potential maintained between the chamber 4 and anode l. The anode l is provided with an aperture or slit 8 aligned with the aperture 6 in chamber 4 and another electrode 9 which has a horizontal base and a pair of walls normal thereto, each such wall being provided with an aperture or slit l0 aligned with the slits 6 and 8. An electrode l I nearly fills the space between the walls of electrode 9, thus forming a small box through which electrons attracted by anode I pass. The electrode 9 is maintained at a potential a volt or so lower than the electrode l l and so accelerates positive gas ions formed in this box downward toward an aperture l2 in the floor of this box.
The tube l is provided with a metalshield or liner I3 which will be described in more detail below, and the end of liner I3 projecting into chamber 2 is capped with a flanged sleeve I4 leaving a slit I5 aligned with slit I2. The space between the electrodes 9 and II contains molecules of gas which it is desired to segregate from each other or otherwise test. Electrons emanating through the slit 8 ionize by impact the molecules just mentioned and a negative potential of about 1000 volts on the electrode gives them an acceleration downward. Some of these molecules pass through the slit I5 into the main body of the tube I.
The tube I is maintained at a considerable d gree of vacuum, for example, l mm. of mercury by a pump connected to a lead-off IS. The chamber 3 contains a metallic diaphragm I! having an aperture slit I8, a second metal diaphragm I9 containing a slit 2| and an electrode 22 which is provided with a lead 23 passing through the tube wall.
The tube thus arranged is placed between the jaws of an electromagnet which sets up a field of nearly normal intensity perpendicular to the plane of Fig. 1. The molecules emerging with a considerable velocity through the slit I pass into this magnetic field which is made of as constant an intensity as possible throughout the length of the curved portion of the tube I. This magnetic field causes the molecules to follow curved paths, all the molecules of the same molecular weight having a path of the same radius, but these radii being different for different groups of molecules which have different molecular Weights. By properly adjusting the strength of the field, it is possible to cause molecules of any one selected molecular weight to follow paths having a radius substantially equal to the radius of curvature of the tube I, and molecules of this particular weight will accordingly pas through the slits I8 and 2| to impinge on the electrode 22. Molecules of other molecular Weights will either strike the walls of the shield or liner I3 and be discharged thereon in a manner about to be described or will strike portions of the flanged collar I4 and their charges will be returned by the lead 24 connected by an external circuit to the cathode of chamber 4.
In order to provide shielding of the greater portion of the tube I from the effects of external electrical fields, the tube I is provided with a liner I3 which is made up in the following way. A piece of metal ribbon, for example, a Nichrome V ribbon, 2 mils thick by A" wide and preferably unannealed, is cut into numerous pieces 3I each having a length slightly greater than the internal perimeter of tube I. A strap 32 which mat be of Nichrome V wide by 3 mils thick is welded to the successive pieces 3|, these overlapping each other as shown in Fig. 3 somewhat like the scales of a fish. The pieces 3I will, for convenience, hereinafter be called scales. The scales 3I are each slightly reduced in width near the point to which it is welded to the strap.
When the welding is complete the scales (H are bent one by one and slipped into a straight glass tube so that they line its walls somewhat as shown in Fig. 5. The natural spring of the metal ribbon tends to force the scales against the surrounding glass tube. The straight glass tube is of the same internal diameter as the cylindrical portion of the tube I. Before the end chambers of the tube I are fused into place on the latter the straight glass tube is placed in alignment with one end of the cylindrical portion of tube I, a wire attached to the liner being fed through the tube I and out its opposite end. By drawing on the wire just mentioned, it is possible to draw the liner out of the straight glass tube and into the curved cylindrical portion of tube I to form a shield therein. Since the successive scales 3I can slide over each other at their edges, the liner can bend into conformity with the curved cylindrical neck of tube I and still form a practically continuous metallic lining for the latter. Holes 33 are preferably provided in advance in the position of the liner which will lie opposite the pump lead I5.
I claim as my invention:
1. A vacuum tube comprising a wall portion of insulating material in the form of a cylinder and a metallic lining for said wall portion comprising a flexible metal strap having fastened thereon a series of overlapping metal scales.
2. A vacuum tube comprising a wall portion of insulating material in the form of a cylinder and a metallic lining for said Wall portion comprising a flexible metal strap carrying a series of overlapping scales of elastic metal.
3. A vacuum tube comprising a wall portion of insulating material in the form of a cylinder having a curved axis and a metallic lining for said wall portion comprising a flexible metal strap having fastened thereon a series of overlapping metal scales.
JOHN A. HIPPLE, JR.
US439345A 1942-04-17 1942-04-17 Vacuum tube Expired - Lifetime US2354122A (en)

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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2475653A (en) * 1945-04-28 1949-07-12 Cons Eng Corp Mass spectrometry
US2486452A (en) * 1945-04-30 1949-11-01 Cons Eng Corp Mass spectrometry
US2544718A (en) * 1948-07-30 1951-03-13 Univ Minnesota Ion collector for mass spectrometers
US2726336A (en) * 1946-01-09 1955-12-06 Sidney W Barnes Calutron receivers
US2850639A (en) * 1946-02-21 1958-09-02 Fred H Schmidt Calutron receivers
US3260844A (en) * 1964-01-31 1966-07-12 Atomic Energy Commission Calutron with means for reducing low frequency radio frequency signals in an ion beam

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2475653A (en) * 1945-04-28 1949-07-12 Cons Eng Corp Mass spectrometry
US2486452A (en) * 1945-04-30 1949-11-01 Cons Eng Corp Mass spectrometry
US2726336A (en) * 1946-01-09 1955-12-06 Sidney W Barnes Calutron receivers
US2850639A (en) * 1946-02-21 1958-09-02 Fred H Schmidt Calutron receivers
US2544718A (en) * 1948-07-30 1951-03-13 Univ Minnesota Ion collector for mass spectrometers
US3260844A (en) * 1964-01-31 1966-07-12 Atomic Energy Commission Calutron with means for reducing low frequency radio frequency signals in an ion beam

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