US2527946A - Tunable microwave device - Google Patents

Tunable microwave device Download PDF

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US2527946A
US2527946A US692535A US69253546A US2527946A US 2527946 A US2527946 A US 2527946A US 692535 A US692535 A US 692535A US 69253546 A US69253546 A US 69253546A US 2527946 A US2527946 A US 2527946A
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layer
friction
chamber
walls
contact
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US692535A
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Ernest G Linder
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RCA Corp
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RCA Corp
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01PWAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
    • H01P7/00Resonators of the waveguide type
    • H01P7/06Cavity resonators
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01PWAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
    • H01P1/00Auxiliary devices
    • H01P1/24Terminating devices
    • H01P1/28Short-circuiting plungers

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  • This invention relates generally to super-high frequency apparatus and more particularly to an improved tunable microwave device of the type utilizing an adjustable tuning piston in a microwaveguide or cavity resonator.
  • the instant invention contemplates the use of relatively hard materials having relatively low coeflicients of friction for the inner walls and the piston contacts of an adjustable cavity resonator, wherein the inner resonator walls are coated or plated with relatively soft, high conductivity material to provide a low resistance surface for the relatively high circulating microwave currents.
  • high conductivity materials such as silver or copper
  • the inner walls of the cavity resonator include channels through the thin high conductivity layer thereon which permit the piston contacts to engage directly with the low friction base substance under the high conductivity layer.
  • the channels should be arranged parallel to the direction of current flow in the resonator walls.
  • the major portion of the inner surface of the cavity resonator still comprises the layer of high electrical oonductivity'material, the resistance thereof to circulating microwave currents is substantially unaffected by the channels which pass therethrough. Also, since low coefficient-offriction materials only are in contact between the movable piston and'the resonator walls, the resultant device is especially eflicient for rapid, mechanically frequency-modulated sys- -2 terns wherein the piston position is rapidly and continuously changed.
  • Figure 1 is a partially cross-sectional elevational view of a preferred embodiment'thereof taken along the section line II of Figure 2; and Figure 2 is a cross-sectional bottom view taken along the section line IIII of Figure 1. Similar reference characters are applied to similar elements throughout the drawing.
  • a typical embodiment of the invention comprises a cylindrical cavity resonator I closed at one end by a plug 3 and having disposed therein a longitudinally adjustable tuning piston 5 including an actuating shaft 1.
  • the walls of the cavity resonator l preferably are of some very hard material such as chromium plated or hardened steel, tungsten, or boron which engage the hard steel or alloy resonator walls through narrow longitudinal channels 13 which are cut through the high electrical conductivity coating I 5 on the inner resonator walls.
  • the area of the actual contact points of the contact fingers 9 is very small, the area of the hard resonator wall base material which must be exposed through the channels [3 also is small, and the circulating currents in the walls of the resonator flow almost entirely in the high conductivity layer l5.
  • the high conductivity layer I5 is not in direct contact with the edges of the piston or the piston contacts, there is relatively little wear or scratching of the relatively soft high conductivity surface.
  • the invention disclosed comprises a novel tunable microwave waveguide or cavity resonator device including a tuning piston wherein the relatively movable elements are constructed of hard, low coefificient-of-friction materials where in con tact, and the non-contacting portions thereof are plated or coated with high electrical conductivity material to provide low resistance paths for circulating microwave currents, and long operating life with uniform operating characteristics.
  • a tunable microwave device including a conductive microwave chamber of hard material having a low coefficient of friction with a movable tuning element disposed therein, the improvement comprising at least one contact finger on said element for contacting the inner walls of said chamber, and a thin layer of high electrical conductivity material disposed upon the inner walls of said chamber for carrying circulating currents thereon, said layer having a plurality of narrow longitudinal channels extending through said layer in registry with said contact fingers for permitting said fingers to slide upon and contact directly with the underlying chamber walls having low coefiicient of friction therewith.
  • a tunable microwave device including a conductive microwave chamber of hard material having a low coeflicient of friction with a movable tuning element disposed therein, the improvement comprising at least one contact finger on said element for contacting the inner walls of said chamber, and a. thin layer of high electrical .conductivity material disposed upon th inner walls of said chamber for carrying circulating currents thereon, said layer having a plurality of narrow longitudinal channels extending through said layer parallel to the direction of current flow in the inner walls of said chamber and in registry with said contact fingers for permitting said fingers to slide upon and contact directly with the underlying chamber walls having low coefficient of friction therewith.
  • a tunable microwave device including a microwave cavity resonator of hard conductive material having a low coefiicient of friction with a movable tuning piston disposed therein, the improvement comprising a plurality of contact fingers on said piston for contacting the inner walls of said resonator, and a thin layer of high electrical conductivity material disposed upon the inner walls of said resonator for carrying circulating currents thereon, said layer having a plurality of narrow longitudinal channels extending through said layer in registry with said contact fingers for permitting said fingers to slide upon and contact directly with the underlying resonator walls havmg w coefiicient of friction therewith.
  • a tunable microwave device including a conductive waveguide of hard material having a low coefficient of friction with a movable tuning piston disposed therein, the improvement comprising a plurality of contact fingers on said piston for contacting the inner walls of said waveguide, and a thin layer of high electrical. con.-
  • said layer having a plurality of narrow longitudinal channels extending through said layer in registry with said contact fingers for permitting said fingers to slide upon and contact directly with the underlying waveguide walls having low coefficient of friction therewith.
  • a tunable microwave device including a conductive evacuated microwave chamber of hard material having a low coeflicient of friction with a movable tuning element disposed therein, the improvement comprising a plurality of contact fingers on said element for contacting the inner walls of said chamber, and a thin layer of high electrical conductivity material disposed upon the inner walls of said chamber for carrying circulating currents thereon, said layer having a plurality of narrow longitudinal channels extending through said layer in registry with said contact fingers for permitting said fingers to slide upon and contact directly with the underlying chamber walls having low coefiicient of friction therewith.
  • a tunable microwave device including a conductive microwave chamber of hard material having a low coefficient of friction with a mov able tuning element disposed therein, the improvement comprising a plurality of contact fingers on said element each having rounded projecting ends for contacting the inner walls of said chamber, and a thin layer of high electrical conductivity material disposed upon the inner walls of said chamber for carrying circulating currents thereon, said layer having a plurality of narrow longitudinal channels extending through said layer in registry with said ends of said contact fingers for permitting said ends of said fingers to slide upon and contact directly with the underlying chamber walls having low coefficient of friction therewith.
  • a tunable microwave device including a microwave chamber of hard material having poor electrical conductivity and a low coefficient of friction with a movable tuning element disposed therein, the improvement comprising a plurality of contact fingers on said element each having rounded projecting ends for contacting the inner walls of said chamber, and a thin layer of high electrical conductivity material disposed upon the inner walls of said chamber and having a thickness at least equal to the skin-thickness for microwave currents at the operating frequncy for carrying circulating microwave currents thereon, said layer having a plurality of narrow longitudinal channels extending through said layer in registry with said ends of said contact fingers for permitting said ends of fingers to slide upon and contact directly with the underlying chamber walls having low coefficient of friction therewith.

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Description

Oct. 31, 1950 E. a. LINDER TUNABLE MICROWAVE DEVICE Filed Aug. 25, 1946 Bnnentor Ernesi allude-r Gttomeg Patented Oct. 31, 1950 I 2,527 ,946 TUNABLE MICROWAVE DEVICE Ernest G. Linder, Princeton, N. J., assignor to Radio Corporation of America, a corporation of Delaware Application August 23, 1946, Serial No. 692,535
'7 Claims. 1
This invention relates generally to super-high frequency apparatus and more particularly to an improved tunable microwave device of the type utilizing an adjustable tuning piston in a microwaveguide or cavity resonator.
Heretofore various types of tuning pistons for waveguides and cavity resonators have been em ployed to vary the effective length of resonant microwave cavities. However, many such slidable pistons have introduced serious power losses and undesirable wave reflections due to faulty electrical contact between the piston and the interior faces of the waveguide or cavity resonator. The terminating piston in such devices carries considerable circulating current and it is highly desirable that the contact resistance be tween the piston and the adjacent Waveguide or resonator walls remain substantially constant.
It is well known that relatively movable surfaces disposed within evacuated chambers have relatively larger coeflicients of friction than is the case with the same materials in air. Furthermore, materials having relatively low coefii- ,cients of friction either in air or in vacuofrequently have poor electrical conductivity and vice versa.
The instant invention contemplates the use of relatively hard materials having relatively low coeflicients of friction for the inner walls and the piston contacts of an adjustable cavity resonator, wherein the inner resonator walls are coated or plated with relatively soft, high conductivity material to provide a low resistance surface for the relatively high circulating microwave currents. However since high conductivity materials, such as silver or copper, have relatively high coeflicients of friction,.the inner walls of the cavity resonator include channels through the thin high conductivity layer thereon which permit the piston contacts to engage directly with the low friction base substance under the high conductivity layer. Preferably, the channels should be arranged parallel to the direction of current flow in the resonator walls. Since the major portion of the inner surface of the cavity resonator still comprises the layer of high electrical oonductivity'material, the resistance thereof to circulating microwave currents is substantially unaffected by the channels which pass therethrough. Also, since low coefficient-offriction materials only are in contact between the movable piston and'the resonator walls, the resultant device is especially eflicient for rapid, mechanically frequency-modulated sys- -2 terns wherein the piston position is rapidly and continuously changed.
Among the objects of the invention are to provide an improved method of and means for tuning microwave resonators and waveguide systems. Another object is to provide an improved microwave tuning piston and cavity resonator having the advantages of high electrical con"- ductivity, low coefficient of friction, and long op erating life. A further object is to provide an improved microwave tunable device comprising a cavity resonator or waveguide structure consisting of low coeflicient-of-friction material upon which is plated or deposited a layer of high conductivity material, and wherein channels are provided through said layer for contact with a movable element. An additional object is to provide an improved tunable microwave device for use in vacuo. A further object is to provide an improved tunable microwave device having long operating life and substantially uniform electri-' cal characteristics.
The invention will be described in further detail by reference to the accompanying drawing of which Figure 1 is a partially cross-sectional elevational view of a preferred embodiment'thereof taken along the section line II of Figure 2; and Figure 2 is a cross-sectional bottom view taken along the section line IIII of Figure 1. Similar reference characters are applied to similar elements throughout the drawing.
Referring to the drawing, a typical embodiment of the invention comprises a cylindrical cavity resonator I closed at one end by a plug 3 and having disposed therein a longitudinally adjustable tuning piston 5 including an actuating shaft 1. The walls of the cavity resonator l preferably are of some very hard material such as chromium plated or hardened steel, tungsten, or boron which engage the hard steel or alloy resonator walls through narrow longitudinal channels 13 which are cut through the high electrical conductivity coating I 5 on the inner resonator walls. Since the area of the actual contact points of the contact fingers 9 is very small, the area of the hard resonator wall base material which must be exposed through the channels [3 also is small, and the circulating currents in the walls of the resonator flow almost entirely in the high conductivity layer l5. However, since the high conductivity layer I5 is not in direct contact with the edges of the piston or the piston contacts, there is relatively little wear or scratching of the relatively soft high conductivity surface.
Thus the invention disclosed comprises a novel tunable microwave waveguide or cavity resonator device including a tuning piston wherein the relatively movable elements are constructed of hard, low coefificient-of-friction materials where in con tact, and the non-contacting portions thereof are plated or coated with high electrical conductivity material to provide low resistance paths for circulating microwave currents, and long operating life with uniform operating characteristics.
I claim as my invention:
1. In a tunable microwave device including a conductive microwave chamber of hard material having a low coefficient of friction with a movable tuning element disposed therein, the improvement comprising at least one contact finger on said element for contacting the inner walls of said chamber, and a thin layer of high electrical conductivity material disposed upon the inner walls of said chamber for carrying circulating currents thereon, said layer having a plurality of narrow longitudinal channels extending through said layer in registry with said contact fingers for permitting said fingers to slide upon and contact directly with the underlying chamber walls having low coefiicient of friction therewith.
2. In a tunable microwave device including a conductive microwave chamber of hard material having a low coeflicient of friction with a movable tuning element disposed therein, the improvement comprising at least one contact finger on said element for contacting the inner walls of said chamber, and a. thin layer of high electrical .conductivity material disposed upon th inner walls of said chamber for carrying circulating currents thereon, said layer having a plurality of narrow longitudinal channels extending through said layer parallel to the direction of current flow in the inner walls of said chamber and in registry with said contact fingers for permitting said fingers to slide upon and contact directly with the underlying chamber walls having low coefficient of friction therewith.
3. In a tunable microwave device including a microwave cavity resonator of hard conductive material having a low coefiicient of friction with a movable tuning piston disposed therein, the improvement comprising a plurality of contact fingers on said piston for contacting the inner walls of said resonator, and a thin layer of high electrical conductivity material disposed upon the inner walls of said resonator for carrying circulating currents thereon, said layer having a plurality of narrow longitudinal channels extending through said layer in registry with said contact fingers for permitting said fingers to slide upon and contact directly with the underlying resonator walls havmg w coefiicient of friction therewith.
4. In a tunable microwave device including a conductive waveguide of hard material having a low coefficient of friction with a movable tuning piston disposed therein, the improvement comprising a plurality of contact fingers on said piston for contacting the inner walls of said waveguide, and a thin layer of high electrical. con.-
ductivity material disposed upon the inner walls of said waveguide for carrying circulating currents thereon, said layer having a plurality of narrow longitudinal channels extending through said layer in registry with said contact fingers for permitting said fingers to slide upon and contact directly with the underlying waveguide walls having low coefficient of friction therewith.
5. In a tunable microwave device including a conductive evacuated microwave chamber of hard material having a low coeflicient of friction with a movable tuning element disposed therein, the improvement comprising a plurality of contact fingers on said element for contacting the inner walls of said chamber, and a thin layer of high electrical conductivity material disposed upon the inner walls of said chamber for carrying circulating currents thereon, said layer having a plurality of narrow longitudinal channels extending through said layer in registry with said contact fingers for permitting said fingers to slide upon and contact directly with the underlying chamber walls having low coefiicient of friction therewith.
6. In a tunable microwave device including a conductive microwave chamber of hard material having a low coefficient of friction with a mov able tuning element disposed therein, the improvement comprising a plurality of contact fingers on said element each having rounded proiecting ends for contacting the inner walls of said chamber, and a thin layer of high electrical conductivity material disposed upon the inner walls of said chamber for carrying circulating currents thereon, said layer having a plurality of narrow longitudinal channels extending through said layer in registry with said ends of said contact fingers for permitting said ends of said fingers to slide upon and contact directly with the underlying chamber walls having low coefficient of friction therewith.
'7. In a tunable microwave device including a microwave chamber of hard material having poor electrical conductivity and a low coefficient of friction with a movable tuning element disposed therein, the improvement comprising a plurality of contact fingers on said element each having rounded projecting ends for contacting the inner walls of said chamber, and a thin layer of high electrical conductivity material disposed upon the inner walls of said chamber and having a thickness at least equal to the skin-thickness for microwave currents at the operating frequncy for carrying circulating microwave currents thereon, said layer having a plurality of narrow longitudinal channels extending through said layer in registry with said ends of said contact fingers for permitting said ends of fingers to slide upon and contact directly with the underlying chamber walls having low coefficient of friction therewith.
ERJNEST G. LINDER.
REFERENCES CITED The following references are of record in the file of this patent:
UNITED STATES PATENTS Number Name Date 2,106,713 Bowen Feb. 1, 1938 2,106,771 Southworth Feb. 1, 1938 2,281,550 Barrow May 5, 1942 2,342,254 Dallenbach Feb. 22, 1944 2,417,785 Slepian -2 Mar. 18, 1947 2,434,508 Okress et al. Jan. 13, 1948
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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2742617A (en) * 1952-08-11 1956-04-17 Gen Electric Tunable cavity resonator
US3209290A (en) * 1963-04-08 1965-09-28 Varian Associates Cavity resonator having spaced walls with corrugated reinforcing means

Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2106713A (en) * 1936-04-21 1938-02-01 Bell Telephone Labor Inc Wave-meter
US2106771A (en) * 1935-09-11 1938-02-01 American Telephone & Telegraph Ultrahigh frequency signaling
US2281550A (en) * 1937-08-14 1942-05-05 Research Corp Electric-circuit element
US2342254A (en) * 1939-07-15 1944-02-22 Dallenbach Walter Resonance device for ultra-short waves
US2417785A (en) * 1943-05-08 1947-03-18 Westinghouse Electric Corp Low-loss conductor for highfrequency currents
US2434508A (en) * 1942-09-02 1948-01-13 Westinghouse Electric Corp Coupling device

Patent Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2106771A (en) * 1935-09-11 1938-02-01 American Telephone & Telegraph Ultrahigh frequency signaling
US2106713A (en) * 1936-04-21 1938-02-01 Bell Telephone Labor Inc Wave-meter
US2281550A (en) * 1937-08-14 1942-05-05 Research Corp Electric-circuit element
US2342254A (en) * 1939-07-15 1944-02-22 Dallenbach Walter Resonance device for ultra-short waves
US2434508A (en) * 1942-09-02 1948-01-13 Westinghouse Electric Corp Coupling device
US2417785A (en) * 1943-05-08 1947-03-18 Westinghouse Electric Corp Low-loss conductor for highfrequency currents

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2742617A (en) * 1952-08-11 1956-04-17 Gen Electric Tunable cavity resonator
US3209290A (en) * 1963-04-08 1965-09-28 Varian Associates Cavity resonator having spaced walls with corrugated reinforcing means

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