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Publication numberUS2773665 A
Publication typeGrant
Publication dateDec 11, 1956
Filing dateFeb 18, 1955
Priority dateFeb 18, 1955
Publication numberUS 2773665 A, US 2773665A, US-A-2773665, US2773665 A, US2773665A
InventorsBerger Netardus N, Norton James P
Original AssigneeHughes Aircraft Co
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
High speed oscillating device
US 2773665 A
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Description  (OCR text may contain errors)

Dec. 11, 1956 N. N. BERGER ETAL 2,773,665

HIGH SPEED OSCILLATING DEVICE Filed Feb. 18, 1955 a M W wz M} Z M Z a lira-.4.

Patented Dec. it, rose HIGH SPEED OSCILLATlN-G DEVICE Netardus N. Berger and James P. Norton, Los Angeles, Calif., assignors to Hughes Aircraft Company, a corporation of Delaware Application February 18, 1955, Serial No. 489,402

Claims. (Cl. 2531) The present invention relates generally to a device for producing oscillatory movement in a member, and relates more particularly to such a device that may be incorporated with switch contact arrangements in order that high speed cyclic operation may be achieved.

In many contemporary mechanical, electrical and pneumatic devices, it has become necessary to produce extremely rapid mechanical oscillations of a member which may be associated with a switch, for example. Such oscillations must be in the nature of from 5000 to 10,000 cycles per minute. In prior high speed mechanically operated switches, or other like oscillating members wherein the particular member was biased in at least one direction by means of a mechanical spring, the mechanical rate of spring action has been an important factor that necessarily must be taken into consideration. In order to increase spring rate, it is well known that the effective force of a spring must be increased, thereby requiring increased operating forces and higher frictional losses with respect to mechanical operating mechanisms. Additionally, with mechanical springs, difiiculties have frequently been encountered relative to fluttering of the spring and/ or fatigue and failure thereof due to the rapidly moving porticns of the metallic spring. Accordingly, it has been found that the best spring flexure type oscillating devices may be operated only up to approximately 1000 complete cycles per minute before fluttering occurs and dangerous situations are encountered that ultimately cause'fatigue and breakage of components.

Furthermore, in prior arrangements intended for a similar purpose, considerable power input has been required in order to effect high speed oscillation, thus causing excessive undesirable wear on various components of the mechanism, frequent replacement of parts and associated time consuming and costly maintenance. These various factors necessarily reduce the overall reliability of the oscillating device.

Accordingly, it is one important object of the present invention to provide a pneumatically operated device for producing high speed oscillation of a member.

Another object of the invention is to provide a novel high speed oscillating device wherein input power requirements for operation thereof are maintained at a minimum.

A further important object of the present invention is to provide a novel switch arrangement and a high speed oscillating contact member adapted for association therewith.

Still another important object of the present invention is to provide a novel high cyclic speed switch operating mechanism that is reliable in operation, efficient and effective in use, and which inherently requires very little maintenance.

A still further important object of the invention is to provide a multiple contact switching arrangement wherein such contacts may be closed by high speed oscillation of a contact carrying member in response to the direction of fluid under pressure upon portions thereof.

Other and further important objects of the present invention will become apparent from the disclosures in the following detailed specification, appended claims and accompanying drawing, wherein:

Figure 1 is a longitudinal sectional view, partially in elevation, showing one form of the member oscillating device of the present invention;

Fig. 2 is an enlarged transverse sectional view showing the contact carrying oscillatory member, as taken substantially as indicated by line 22, Fig. 1;

Fig. 3 is an enlarged fragmentary sectional view, taken as indicated by line 33, Fig. 4, through the fluid directing nozzle, shown in conjunction with a modified form of switching arrangement; and

Fig. 4 is a transverse sectional View taken substantially as indicated by line 4-4, Fig. 3.

With reference to the drawing, the oscillation producing device of the present invention is shown, in Fig. 1, as associated with electrical switching arrangement; however, it is to be understood that the present basic system utilized for oscillatinga switch member may be incorporated with other types of mechanisms such as, for example, pneumatic or hydraulic valve arrangeme'ntsywithout departing from the spirit and scope of the present invention. As shown, the device of the present invention includes a base upon which a bearing cage 11 is mounted. One end of the bearing cage 11 is closed by means of a closure member 12, with ball bearings 13 being supported within the cage. A' rotatable member, in the form of an elongated tube 14, is rotatably journalled in the bearings 13. The tube 14 has an inner bore 15, one end of which is open as at 16. The other end of the tube 14 is closed by means of a closure member 17. A nozzle 18 is formed through the closure 17 adjacent the outer periphery thereof with the inner end of the nozzle communicating with the interior bore of the tube 14 adjacent the outer periphery of the bore.

An oscillatory member, in the form of plate 29, having notches cut away as at 20a, is positioned in space relationship to an outer surface 21 of the closure 17. The

plate 26 is supported on a transversely disposed shaft 22,

Fig. 2, the ends of which are journalled, by means of needle bearings 23, in brackets 24 that are disposed outwardly from a support 25 which is, in turn, secured to the base 10. The upper and lower portions of the plate 20 are adapted to carry a pair of contacts 26 that are arranged on a line disposed substantially normal to the oscillatory axis of the plate.

The support 25 also serves to retain a pair of adjustably disposed contact members 27 that are adapted for cooperation with the contacts 26 carried by the plate 20. The inner ends of the contact members 27 are positioned in slight spaced relationship to a neutral oscillatory position of the plate 20, and serve to limit the oscillatory magnitude of the plate. The contact members 27 may have leads 28 connected thereto by means of nuts 30, the nuts 30 also serving to lock the relative positions of the contact members 27 which threadably engage in suitable openings iu'the support 25.

The tube 14' has affixed thereto, adjacent one end of the cage 11, a gear 31 which is held in position by means of a set'screw 3 2. The gear 31 is adapted to mesh with a driving gear 33 that is supported on a shaft 34 extending outwardly from a synchronous motor 35. The motor 35 is supported on a bracket 36'which has a portion 37 that serves as a guard for the gears 31 and 33. The bracket 36 is supported as at 38 in one end of the bearing cage 11. In accordance with conventional practice, the electric motor 35 may be controlled through a suitable rheostat 40, with electrical power input through suitable connections 41.

A non-rotatable sleeve 42 is adapted for disposition within the bore 15 of the tube 14 through the open end 16 thereof. The sleeve 42 is formed as an inner end portion of a fitting 43 that threadably engages in an opening in the closure 12, as at 44. The sleeve 42 has an axial bore 45, the outer end of which is conically outwardly tapered as at 46. The fitting 43' is adapted for connection with a conduit 47 which, in turn, extends to a suitable source of fluid under constant regulated pressure.

It may, thus, be seen that fluid under pressure as, for example air, may be directed through the bore 45 of the sleeve 42 and into the bore 15 of the tube 14. The air will then flow through the tube 14 and outwardly therefrom, by Way of the nozzle 18, for impingement thereafter upon the peripheral area of the upper and lower portions of the plate 20. The air flowing through the tube 14 is directed toward the nozzle 18 by means of a deflection member 48 that is positioned within the bore 15 adjacent the inner surface of the closure 17. The deflection member 43 is retained in position by means of a screw 15.

In operation of the present device, the synchronous motor 35 is energized whereby to rotate the driving gear 33 and to drive the gear 31 and tube 14. Simultaneously, fluid under pressure is admitted through the conduit 47 and sleeve 42 into the interior bore 15 of the tube 14 and outwardly through the nozzle 18. Inasmuch as the nozzle 13 is rotated with the tube 14, the fluid emitting from the nozzle will strike the portions of the plate in an intermittent manner and cause the plate 20 to be oscillated on the shaft 22 to bring one after another of the contacts 26 in alternating contact with one after another of the contact members 27. The cyclic speed of oscillation of the plate 20 may be determined by adjustment of the rheostat 40 and associated control of the rotary speed of the tube 14.

It may thus be seen that very little force will be required to oscillate the plate 20. The relative size and weight of the plate 20 is suflicient to maintain the movable elements of the mechanism at a low inertia level, whereby to permit rapid oscillation thereof. Additionally, it is to be noted that the input power requirements from the motor 35 may be extremely low due to the lack of friction either in the rotatable supporting mechanism of the tube 14 or due to the non contacting association between the tube and the plate 20. This latter factor may be seen as being especially important when considered in the light of prior arrangements designed for a similar purpose, wherein cams or other mechanical operating arrangements physically cooperate with an oscillating member.

As shown in Figs. 3 and 4 and as indicated hereinbefore, the present device may be utilized with a variety of devices or switching arrangements without departing from the spirit and scope hereof. With reference primarity to Fig. 3, an oscillatory plate 20' may be provided with an annularly disposed ring of contacts 26 that are adapted for cooperation with a plurality of contact members 27. In this particular arrangement, it is necessary that the plate 20 be universally mounted as by means of a ball 60 disposed in a socket 61 in the support 25. The plate 20 may be attached to the ball 60 by means of an extension stem 62 and a screw 63 disposed centrally through the plate 20'. In order to prevent inadvertent rotation of the disk shaped plate 20', the ball 60 may have a pair of protuberances 63 disposed on an axis thereof and extending outwardly therefrom. The protuberances 63 may be loosely disvposed within and spaced from the bottoms of recesses 64 in the sides of the socket 61. This particular construction will enable the plate 20 to move in a universal manner while still preventing undue rotation thereof as would disturb the alignment between the contacts 26' and the contact members 27'. Thus, as the tube 14 is rotated, the nozzle 18 will be directed toward a peripheral area of the plate 20' whereby successively and in a circular manner to effect contact between one after another of the contacts 26' and the contacts 27.

While the source of the motive fluid is immaterial in the present invention, as shown in Fig. l, it may be desirable to provide a self-contained unit whereby a suitable compressor may be driven from a free end of the motor shaft 34, with the outlet therefrom being conducted to the tube 14 by way of a conduit 71 connecting with the conduit 47. With an arrangement of this type, it will be seen that the entire switch operating mechanism or member oscillating device may be self-contained.

Having thus described the invention and the present embodiments thereof, it is desired to emphasize the fact that many modifications may be resorted to in a manner limited only by a just interpretation of the following claims.

What is claimed is:

1. In a device for producing oscillatory movement: a member mounted for oscillation about an axis; means positioned adjacent said member for limiting oscillatory movement of said member; a rotatable structure; a nozzle carried by said structure, said nozzle being positioned adjacent to and directed toward said member at a position spaced from the axis of oscillation thereof; passage means forming a portion of said rotatable structure for directing fluid under pressure from a source through said nozzle; and means for rotating said rotatable structure.

2. A device for producing oscillatory movement comprising: a base; a member mounted for oscillation on said base and on an axis; a relatively flat surface formed on said member; a rotatable structure having an end portion disposed adjacent to and in spaced relationship to said surface; a nozzle in said end portion, said nozzle being directed toward a peripheral area of said surface at a position spaced from said axis of oscillation of said member; means carried by said base for limiting oscillation of said member; driving means connected with said structure for rotating said structure; and means connected with said rotatable structure for directing fluid under pressure from a source through said nozzle, where by to effect oscillation of said member.

3. A device for producing oscillatory movement comprising: a base; a member mounted for oscillation on said base and about said axis; a relatively flat surface formed on said member; an elongated rotatable structure having an end portion disposed adjacent to and in spaced relationship to said surface; a nozzle in said end portion, said nozzle being directed toward a peripheral area of said surface at a position spaced from said axis of oscillation of said member; means carried by said base for limiting oscillation of said member; driving means connected with said structure for rotating said structure; and non-rotatable means directed into said structure for directing fluid under pressure from a source through said structure and said nozzle, whereby to effect oscillation of said member.

4. A device for producing rapid oscillatory movement comprising, in combination: a base structure; a plate; means for mounting said plate for oscillatory movement relative to said base structure and about an axis; means carried by said base structure for limiting oscillatory movement of said plate; a tube; a closure disposed in one end of said tube, said closure being disposed adjacent to and in spaced relationship to said plate; a nozzle provided through a peripheral portion of said closure, said nozzle being directed toward a peripheral area of said plate at a position spaced from the axis of oscillation of said member; means mounted on said base structure for rotatably supporting said tube; driving means connected with said tube for rotating said tube; and means carried by said base structure for directing fluid under pressure into said tube, said fluid being adapted thereafter to flow outwardly from said tube through said nozzle for im- 5 pingement upon said plate, thereby to efifect oscillation thereof.

5. A device for producing rapid oscillatory movement comprising, in combination: a base structure; a plate; means carried by said base structure for mounting said plate for oscillatory movement relative to said base structure and about an axis; means for limiting oscillatory movement of said plate; a tube; a closure disposed in one end of said tube, said closure being disposed adjacent to and in spaced relationship to said plate; a nozzle provided through a peripheral portion of said closure, said nozzle being directed toward a peripheral area of said plate at a position spaced from the axis of oscillation of said member; means mounted on said base structure for rotatably supporting said tube; driving means con- 15 nected with said tube for rotating said tube; non-rotatable means carried by said base structure for directing fluid under pressure into said tube, said fluid being adapted thereafter to flow outwardly from said tube through said nozzle for impingement upon said plate, thereby to effect oscillation thereof; and means disposed Within said tube for directing said fluid toward said nozzle.

References Cited in the file of this patent UNITED STATES PATENTS 1,322,506 Austin Nov. 25, 1919 2,611,051 Kolff Sept. 16, 1952 FOREIGN PATENTS 116.693 Australia May 10, 1943

Patent Citations
Cited PatentFiling datePublication dateApplicantTitle
US1322506 *Jul 2, 1916Nov 25, 1919Austin Organ CompanyJohn i
US2611051 *Oct 4, 1951Sep 16, 1952Santen Kolff Peter VanRotary contactor device
AU116693B * Title not available
Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US2852636 *Aug 12, 1955Sep 16, 1958Block Alvin VAir jet commutator
US2855473 *Dec 9, 1955Oct 7, 1958Jacob RabinowFluid operated switch
US3013134 *Sep 30, 1958Dec 12, 1961Jacob RabinowFluid operated switch
US3056003 *Oct 2, 1958Sep 25, 1962Jacob RabinowFluid operated switch
US3076065 *Aug 2, 1960Jan 29, 1963John DimeffHigh-speed low-level electrical stepping switch
US4598238 *Apr 24, 1985Jul 1, 1986Albany International Corp.Electro-mechanical shower oscillator for papermaking machine
US5351885 *Dec 28, 1993Oct 4, 1994Taiho Industries Co., Ltd.Liquid jetting apparatus including position change and detector mechanisms
US6264125Dec 9, 1999Jul 24, 2001Brunswick CorporationAsymmetric oscillation mechanism for a spinning reel
US7837132 *May 16, 2003Nov 23, 2010S.C. Johnson & Son, Inc.Automated cleansing sprayer
US8550378Oct 15, 2010Oct 8, 2013S.C. Johnson & Son, Inc.Automated cleansing sprayer
Classifications
U.S. Classification415/132, 200/81.90R, 239/380, 200/19.6, 200/81.00R, 239/263.1, 251/12
International ClassificationB06B1/18
Cooperative ClassificationB06B1/18
European ClassificationB06B1/18