US2846753A

US2846753A - Method of making thin metal sections vacuum tight

Info

Publication number: US2846753A
Application number: US304968A
Authority: US
Inventors: Michael J Zunick; John E Illinworth
Original assignee: General Electric Co
Current assignee: General Electric Co
Priority date: 1951-09-28
Filing date: 1952-08-18
Publication date: 1958-08-12
Anticipated expiration: 1975-08-12
Also published as: GB715669A; FR1062971A; DE942828C

Description

1958 M. J. ZUNICK ETAL 2,846,753 METHOD'OF MAKING THINMETAL SECTIONS VACUUM TIGHT Original Filed Sept. 28, 1951 '-m 57 MICHAEL J. ZUNIC 52 %////A7///4 JOHN E. ILLINGWORTH 48 9M :94 @444 ATTORN EY 'wardly of the envelope.

2,846,753 Patented Aug. 12, 1958 METHOD OF MAKING THIN METAL SECTIONS VACUUM TIGHT Michael J. Zunick, Greenfield, and John E. Illingworth,

Waukesha, Wis., assignors to General Electric Company, a corporation of New York Original application September 28, 1951, Serial No. 248,766. Divided and this application August 18, 1952, Serial No. 304,968

3 Claims. (Cl. 29-4514) The present invention relates in general to vacuum sealing, and has more particular reference to means for and method of insuring vacuum tightness at relatively thin sections in metal castings, the invention more especially pertaining to the assurance of vacuum tightness in the evacuated envelopes of electron flow devices, such as X-ray generating tubes, more particularly at thin wall sections of cast metal comprising portions of the anode of the flow device and forming portions of its evacuated envelope. The invention comprises subject matter divided from a co-pending application'for United States Letters Patent, Serial No. 248,766, filed September 28, 1951.

An X-ray generator tube comprises an electron flow device embodying an electron emitting cathode, ananode forming an electron target, and a sealed and evacuated envelope enclosing the anode and cathode in spaced apart facing relationship within the envelope. X-rays are produced in such a tube by applying electrical potential between the anode and cathode for electron driving purposes, in order to impel electrons, emitted at the cathode, toward and upon the electron target portions of the anode, at relatively high velocity, in order to constitute the anode target portions as an X-ray source. The anode and cathode are commonly sealed in openings formed in the envelope,.in fashion disposing portions of the anode and cathode structure in said openings, thereby constituting such :portions as parts of the sealed and'evacuated envelope. I

impingement of electrons on the'anode target results in the generation ofsubstantial quantities of heat, which, especially inhigh powered tubes, tends to deteriorate and ultimately to destroythe target. In the interests of efficient X-ray production, the generator tube is usually operated under load conditions producing, in the target, high temperatures of the order of the melting temperature of the target material; and various expedients are employed for cooling the anode target in order to hold the same at a temperature, during operation of the tube, safely below theteinperature at which the target would melt or become otherwise damaged or burned.

Water/oil and air are commonly employed as media fortransferring heat away from the anode targetsof X-ray generating tubes. Where air is employed as a cooling medium, it is common to providev the anode structure with an extension projecting outwardly of the envelope and carryingheat radiating fins or other heat dissipating means ,so that anode heat may be conducted from the target,.through the body of the anode to the-radiating fins, and dissipated thence to circumambient atmosphere out- Such cooling by air is usually employed only in relatively low power generators, since aircooling is inherently incapable of dissipating heat at a sufficiently high rate to accommodate the relatively large quantities of anode heat generated in high power tubes when in operation. Accordingly, for high power tube cooling purposes, it is common to continuously deliver a cooling medium, such as oil or water, through a chamber formed in the anode structure immediately behind the target, the medium being circulated between the chamber and an external cooler to thus absorb heat from the target into the circulating medium and then extract the heat from the medium outwardly of the generator and dissipate it to atmosphere. The medium thus circulated in the chamber formed in the anode structure, immediately behind the target, is normally under pressure of the order of atmospheric pressure, as distinguished from the low pressure condition-s within the evacuated envelope, so that the sectional thickness of the target portions of the anode "structure, at said chamber, are required to be vacuum tight in order to preserve the evacuated condition within the generator envelope.

It is desirable, however, to make the said target portions as thin as possible, in the interests of rapid heat dissipation from the anode target to the circulating medium in the chamber. Anode structures, however, are commonly made of cast metal, usually copper, the target usually comprising a button of refractory material, such as tungsten, embedded in the copper anode structure adjacent the cooling chamber. It has been found necessary, in the past, to design X-ray tube anodes with walls of thicknesses of the order of not less than of cast metal, behind the target button and between it and the cooling chamber, because of the relatively coarse granular structure obtained during the casting operation, which tends to open up along the grain-boundaries of the constituent material during subsequent heat processing of the casting.

An important object of the present invention is to substantially reduce the sectional thickness in metal castings, as between the target button and the cooling chamber in an X-ray anode structure, while maintaining adequate vacuum tightness at such section of reduced thickness; a further object being to provide an X-ray anode structure embodying minimal wall thickness immediately behind the target button, in the interests of rapid heat dissipation.

Another important object is to accomplish minimal sectional thickness in cast metal structures, while maintaining vacuum tightness therein, by incorporating, in the structure, a relatively thin layer or sheet of relatively dense material, such as molybdenum, as a vacuum maintaining insert in the structure at the place or station where vacuum tightness is desired.

Another important object is to incorporate, in a casting comprising a thin cast metal section, a thin plate or shell of dense, substantially impervious material, in order to render the thin cast metal section vacuum tight; a further object being to incorporate such shell or layer in the casting during the formation thereof as such, by applying the shell or plate as an insert in the casting mold and casting the metal into the mold in position to envelop and embed the insert in the cast metal.

Another important object is to provide an X-ray tube anode comprising a metal casting carrying a target button embedded therein at a relatively thin wall portion which defines a coolant circulating chamber in the structure, the casting incorporating a thin layer of molybdenum enveloped in the casting between the button and the cooling chamber.

The foregoing and numerous other objects, advantages and inherent functions of the invention will become apparent as the same is more fully understood from the following description which, taken in conjunction with the accompanying drawings, discloses preferred embodiments of the invention for the purpose of demonstrating the same.

Referring to the drawings:

Fig. 1 .is a sectional view of an X-nay generating tube having an anode structure of cast metal, having a thin 3 Wall section containing a vacuum maintaining insert in accordance with the present invention;

Fig. 2 is an enlarged sectional view taken through the anode structure shown in Fig. 1;

Fig. 3 is a sectional view taken substantially along the line 33 in Fig. 2;

Fig. 4 is a sectional view taken through another anode structure embodying the invention;

Fig. 5 is a sectional view taken substantially along the line 5-5 in Fig. 4;

Fig. 6 is an exploded view illustrating the manner of mounting the pre-formed target button and the vacuum sealing shell or layer as inserts in an anode casting mold; and

Fig. 7 is a sectional view showing another anode structure embodying the invention.

To illustrate the invention, the drawings show an X-ray generating tube 11 comprising a cathode 12 embodying an electron emitting element 13, an anode 14 forming an electron target 15, and a sealed evacuated envelope enclosing and supporting the anode and cathode in spaced apart facing relationship within the tube. While the invention is not necessarily limited to any particular form, construction or configuration of the envelope, or of the cathode 12, the envelope, as shown, may comprise a tubular glass element 16 having reentrant

end portions

17 and 17, forming openings at the opposite ends of the envelope. These end portions may be circumferentially sealed respectively to the anode and cathode structures, in order to hermetically seal the envelope at said openings and to mechanically support the anode and cathode structures respectively upon the

reentrant portions

17 and 17, so that the anode and cathode structures seal said openings and form parts of the envelope structure within the

reentrant portions

17 and 17.

The emitting element 13 may comprise a filament suitably supported on and insulated from the cathode structure 12, the filament being connected with lead conductors 18 adapted for connection with a suitable power source outwardly of the envelope, for the purpose of energizing the filament for electron emission. The filament may be connected with the lead conductors 18 through suitable envelope seals, preferably formed in the envelope forming parts of the cathode structure, at the inner end of the reentrant portion 17.

It will, of course, be understood that the generator tube 11 may be operated for the production of X-rays at the target 15, by energizing the filament 13 for electron mission, as by connecting the conductors 18 with a suitable source of emitter energizing power, while simultaneously applying electron driving potential between the cathode and the anode target, as by connecting the anode and one of the conductors 18 with a suitable source of electron driving potential outwardly of the envelope. To this end, the necessary electrical connection with the anode may be made at or through the outwardly exposed envelope forming parts thereof disposed within the reentrant portion 17.

Electrons emitted by the filament 13, when energized, may travel as an electron beam 19 from the filament 13 under the influence of the anode-cathode electron driving potential, and impinge upon the facing surface of the target 15, thereby constituting the target as a source of Xrays which may be projected thence as an X-ray beam 20.

The present invention is not necessarily limited to any particular anode shape, style or configuration. The :anode may comprise a body 21 formed of cast metal, such as copper, into which is set a target button 22 of suitable refractory target material, such as tungsten. Behind the target button 22, the body 21 may form a wall 21 defining a cavity 23 for the circulation of a cooling fluid in heat exchange relationship with the button 22, through the wall 21', for the continuous cooling of the target, the sectional thickness of the cast metal wall 21 behind the button 22 being of the order of or less, which is ordinarily insuflicient to provide vacuum tightness in a cast metal wall of such thickness. In order to insure vacuum tightness in said relatively thin section of cast metal behind the button 22, a layer 24 of dense, impervious sheet material is embedded in the Wall 21. As shown more particularly in Figs. 1, 2 and 3, the layer 24 may comprise a cup-shaped element having a bottom wall 25 extending in the wall 21' immediately behind the target button 22, the vertical spacement between the facing surfaces of the button 22 and the wall 25 being of the order of or less.

The member 24 preferably comprises molybdenum and has wall thickness of the order of from 0.005" to 0.010" so that the combined thickness of copper, molybdenum, and the material of the target 21, between the cathode facing surface of the target button and the chamber 23, is of the order of A5", or less, of which distance the thickness of the target button accounts for about The anode structure, also, if desired, may be formed with staggered partition forming fins 26 and 26' extending in the chamber 23. These fins may be integral with the side and bottom walls of the cavity 23 and may include a pair of spaced apart lateral fins 26 extending from one side of the cavity toward the opposite side thereof, as shown more particularly in Fig. 3 of the drawings, and a central fin 26' spaced from and extending medially between said lateral fins from the opposite side of the cavity 23. These fins may serve to strengthen the wall structure, and will also serve as deflecting baffles for cooling fluid circulated in the chamber 23, as hereinafter more fully described.

The anode structure may also include a sleeve-like extension 27, one end of which may be brazed or otherwise sealingly secured on the casting 21, as at 28, in open communication with the cavity 23. The opposite or open end of the member 27 may be fitted with a cover member 29 carrying the outer end of a tube or pipe 30 in position extending outwardly of the cover member 29 for connection with a source or cooling fluid. The inner end of the pipe 30 may be sealed, as at 31, in an opening 32 formed in a preferably metal disk 33.

This disk may be sized to extend snugly within the cavity 23 in position overlying the wall remote edges of the

fins

26 and 26, the opening 32 being disposed opposite the wall remote end of the fin 26'. Outwardly of the fins 26, the disk 33 may be formed with a pair of cut-out openings 34; and the end closure member 29 may be formed with an outlet opening 35. A suitable cooling fluid may be delivered, as by means of a pump or other circulating device, through the pipe 30 from a source of such fluid disposed outwardly of the X-ray generator tube. The cooling fluid may pass thence through the opening 32 into the cooling chamber 23. Such fluid may travel in the chamber 23 through the channels defined by and between the baffles 26 and 26' in heat exchange relationship with the target button through its supporting wall portions of the anode. The cooling fluid may be discharged from the chamber 23 through the openings 34 into the sleeve-like member 27, and may pass thence through the outlet opening 35 which, if desired, may be connected with the external source of cooling fluid, preferably through suitable means for cooling the fluid for recirculation to the chamber 23.

In order to seal the anode in the envelope member 16, the body 21 of the anode may be formed with a pcripheral shoulder 36 upon which is sealed, as by welding or brazing, a cup-shaped seal member 37 having annular skirt portions forming a lip adapted to form a circumferential glass-to-metal seal 38 with the reentrant envelope portion 17, at the inner end thereof. The anode may thus be sealingly mounted and supported on the envelope member 16 so that the seal member 37, as well as portions of the anode including the target supporting wall portions 21', may form portions of the envelope structure closing the opening formed at the inner end of the reentrant portion 17. V

The present invention, of course, is not necessarily limited to the form and arrangement of the parts of the anode structure. As shown more particularly in Figs. 4 and 5 of the drawings, the body 21 may be formed with asingle medial partition wall 26" formedintegral with the opposite .side walls of the chamber 23 and dividing it into a pair of compartments 23' on opposite sides of the partition, said partition ,wall having an edge spaced from the bottom 25 of the cup-shaped member to define a slot or opening 23". between said edges and the bottom of the cup. This slot serves to interconnect the compartments 23 and to assure that the cooling medium, in flowing in the chamber fromone compartment to the other, will pass immediately behind the target, in efficient heat exchange relation therewith.

The disk 33, which covers the open side of the chamber 23, in Figs; 4 and 5, may be formed with inlet and outlet openings 32 and 34' disposed therein in position respectively communicating with the compartments 23 on opposite sides of the walls 26", the inlet pipe 30 being sealed in the opening 32, at the inner end of said pipe. The disk 33 also may be sealed at its edges to the inner end of the sleeve-like extension 27, which, in turn, may be sealed in the body 21 as at 2 8, and a sealing skirt 37, making a glass-to-metal seal 38 with a reentrant glass envelope portion 17, may be sealed, as at 36, upon peripheral shoulder portions of the body 21.

An enclosing, preferably sheet metal, shell 40 may be applied upon the body 21 and secured in position, as by crimping the peripheral portions 41 of the shell into locking engagement in circumferential grooves 42 formed in the body 21. The shell 40 may include skirt portions 43 extending around and enclosing the glassmetal seal 38 to protect the same from stray electron impingement. The shell may also be formed'with portions 44 enclosing the target end of the anode, such portions being formed with an opening 45 in alinement with and between the electron emitting element of the cathode and the anode target formed by the button 22.

It is, of course, also possible to incorporate structures embodying the present invention in other types of anodes, including anodes for use in X-ray generators of the sort shown in United States Letters Patent No. 2,356,645, issued August 22, 1944, on the invention of Z. J. Atlee and H. W. Brackney. Such an anode is shown in section, in Fig. 7, and may comprise a tubular metal sleeve 46, forming a portion of the envelope of the generator tube, a target structure 47 being sealed in the end of the tube in position to be bombarded by electrons emitted by a cathode enclosed in and supported by the tube envelope at the target remote end of the tube 46. The cathode is thus in position to emit an electron beam longitudinally through the tube 46 for impingement upon the target. As shown in Fig. 7, the target structure 47 may comprise a body 21 of cast metal, such as copper, in which a target button 22 of refractory material, such as tungsten, is set, the structure including a disk or plate 25 of dense, impervious material, such as molybdenum, enveloped in the copper body of the target structure behind the target button 22, the body 21 including an outwardly extending peripheral flange 48 to facilitate the sealing of the target structure 47 in the end of the tube 46, as by welding or brazing the tube end to said flange.

Anode structures embodying the present invention, regardless of their shape or configuration, may be formed by placing the target button 22 and the member 25, Whether formed as a cup or as a plate, as inserts in a suitable casting mold in which the inserts may be anchored. To this end, as shown more particularly in Fig. 6 of the drawings, the target button 22 may be anchored on a mounting plate 49, preferably comprising graphite, by means of molybdenum anchoring pins 50, said pins 6 havingends secured in openings 51 in the anchorplate. The-member 25, whether the same comprises a flat plate as shown in Fig. 7, or the bottom of a cup-shaped member of the sort shown in Figs. 3 and 4, may be anchored on the mounting plate 49 in stacked relationship with respect to the button 22, as by means of molybdenum anthe member 25 is supported in spaced parallel relationship above the target button 22, the vertical distance between the facing surfaces of the member 25 and the button 22 being equal to the diameter ofrthe hooked disk retaining ends of the pins 50. The

inserts

22 and 25, thusanchored on the mounting plate 49, may be fastened in a suitable mold shaped in conformity with the desired shape of the anode body 21, and copper may then be cast into the mold, upon the so mounted

insert elements

22 and 25 in order to embed and envelop said elements in the casting in proper relative position therein, the button 22, in effect, being brazed to and upon the member 25, by the intervening cast material which enters between the space defined by the hooked portions of the anchor pins 50, between the facing surfaces of the

elements

22 and 25. The casting operation is preferably accomplished under vacuum conditions. After the casting operation has been completed and the anode structure removed from the mold, the mounting disk 49 may be stripped from the casting and the projecting ends of the

pins

50 and 52 may be removed, leaving portions of the anchoring

members

50 and 52 embedded in the cast material in the edges of the target button.

It will be seen from the foregoing that the present invention provides a novel method of insuring vacuum tightness in the metal casting comprising the thin wall section 21' which extends behind the target button 22 and between it and the chamber 23, such wall section comprising a part of the evacuated envelope of the X-ray tube. This is accomplished by embedding in said section a relatively thin layer of dense, impervious material, such as molybdenum. The resulting structure is not only vacuum tight at said thin wall section, but said wall section,

being thin, allows for the rapid transfer of heat from the target button 22 to the cooling fluid in the chamber 23.

X-ray anodes incorporating the novel features of the present invention not only show improved and efficient anode cooling characteristics; but the incorporation of integral coolant guiding baffles, such as the

baffies

26 and 26, in the anode structure eliminates the necessity of assembling relatively more expensive conventional cooling coils in the chamber 23, the guiding baffles 26 and 26'. together with the inexpensive cover disk 33, being a cost reducing improvement in fluid cooled X-ray tube anodes.

It is thought that the invention and its numerous attendant advantages will be fully understood from the foregoing description, and it is obvious that numerous changes may be made in the form, construction and arrangement of the several parts without departing from the spirit or scope ofthe invention, or sacrificing any of its attendant advantages, the forms herein being preferred embodiments for the purpose of illustrating the invention.

The invention is hereby claimed as follows:

1. The method of making vacuum tight an X-ray tube anode of cast metal having a target button mounting wall of relatively thin sectional dimension, which comprises pre-forming, as separate elements, the target button and a vacuum sealing member comprising a thin layer of dense impervious metal, mounting said button and sealing member in closely spaced, surface facing relation as inserts in a mold, and then casting a suitable anode metal into the mold under vacuum conditions to envelop and embed said sealing insert in the cast metal comprising said mounting wall, between the opposite faces thereof,

and to apply a joining layer of the cast metal between the closely spaced facing surfaces of said inserts to integrate the same by and with said joining layer.

2. The method of rendering a thin cast metal wall section vacuum tight, whereby the same may be employed for rapid heat transfer therethrough while exposed to substantial pressure differentials on opposite sides of said section, which comprises mounting a layer of dense, impervious, heat conductive metal forming a vacuum sealing shell as an insert in a casting mold, and then casting a suitable wall forming metal, capable of brazingly joining with the material of said shell, into the mold in position to envelop and embed said sealing shell in the cast metal forming said wall section, between the opposite faces thereof.

3. The method of making vacuum tight an X-ray tube anode of cast copper, having a target button mounting wall of relatively thin sectional dimension, which comprises preforming, as separate elements, the target button and a vacuum sealing member comprising a thin layer of dense, impervious molybdenum, mounting said button and sealing member in closely spaced, surfacefacing relation as inserts in a casting mold, and then casting copper into the mold under vacuum conditions, to envelop said sealing member in said copper, between the opposite faces of said mounting wall, and to embed said button in the copper, at a face of said wall, while applying a joining layer of copper between the closely spaced facing surfaces of said inserts to integrate the same by and with said joining layer.

References Cited in the file of this patent UNITED STATES PATENTS