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US3600537A - Switch - Google Patents

Switch
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US3600537A
US3600537AUS816322AUS3600537DAUS3600537AUS 3600537 AUS3600537 AUS 3600537AUS 816322 AUS816322 AUS 816322AUS 3600537D AUS3600537D AUS 3600537DAUS 3600537 AUS3600537 AUS 3600537A
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tube
pinching
spring
switch
actuator
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US816322A
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Robert H Twyford
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MECHANICAL ENTERPRISES Inc
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MECHANICAL ENTERPRISES Inc
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Abstract

An electrical switch including a resilient deformable tube filled with an electrically conductive liquid and a pair of relatively movable pinching elements disposed on opposite sides of the tube. The elements are mounted for movement between tube pinching and tube releasing positions, whereby in the tube pinching position the liquid in the tube is parted to open an electrical circuit. The switch also includes a spring-loaded snap-action mechanism operably connected to at least one of the elements for snapping the same from one of its positions to the other.

Description

United ties Patent 1 ame $37 [72] Inventor Robert 1111. Twytord 1,795,907 3/1931 73/3783 Falls Church, Va. 2,024,362 12/1935 74/100 [21] Appl. NO. 316,322 2,332,883 10/1943 74/100 [22] Filed Apr. 15, 1969 2,374,435 4/1945 200/67 [45] Patented Aug. 17, 1971 2,512,306 6/1950 200/67 {73] Assignee Mechanical Enterprises llneorgporated 2,574,869 1 1/195 1 337/88 3,133,170 5/1964 Nanninga .1 200/67 Primary Examiner- Robert K. Schaefer 54 HTQ Assistant Examiner-H. J. Hohauser 15 claims, 3 Drawing m Attorney-Birch, Swindler, McKie 84 Beckett [52] 10.5. CI 200/1152, m
200/67 ABSTRACT: An electrical switch including :1 resilient 1 lint-Cl 4 4 "M0111! 29/00 deformable tube filled with am electrically conductive liquid 1 Field of Search 200/67 and at pair of relatively movable pinching elements disposed 67 2- I52 on opposite sides oi the tube, The elements are mounted for movement between tube pinching and tube releasing posi- [56] Reference Cited tions, whereby in the tube pinching position the liquid in the UNITED STATES PATENTS tube is parted to open an electrical circuit. The switch also in- 2,420,880 5/1947 Hethcrington ZOO/()7 D eludes a spring-loaded snap-action mechanism operubly con- 2,72(),562 10/1955 McLaughlin 200/152}; nected to at least one of the elements for snapping the same 3,177,327 4/1965 Weiss ZOO/152.9 fr n its p sitions to the other Field of the Invention This invention relates to electrical switches and particularly to switches which include a pinchable tube filled with an electrically conductive fluid.
Description of the Prior Art Various switches of the general type described above (which are typified for example, in US. Pat. No. 2,195,199) have been proposed in the past in an attempt to deal with certain problems which have particularly plagued the electrical communications and computer industries. These problems include, for example, the fact that certain prior art switches which have hard metal contact points as well as certain mercury switches have been found to be position sensitive and subject to contact oscillation requiring bounce gates in the circuitry. Further, because of certain arcing and contamination problems hard contacts are subject to pitting and the like which impedes proper timing and imposes undesirable voltage drop characteristics.
However, even the previous mercury switches having structures which include a pinchable tube filled with an electrically conductive liquid have experienced certain difficulties, such as, unpredictable responses in making or breaking the circuit.
SUMMARY OF THE INVENTION The shortcomings inherent in the prior art switches are substantially overcome by the novel switch of the instant invention which combines the mechanical advantages of a snap-action switch with the electrical properties of a mercury switch. This is particularly accomplished in a switch which includes a tube filled with an electrically conductive liquid and structure operable for pinching the tube to part the liquid and open an electrical circuit. The structure comprises a pair of spaced pinching elements disposed on opposite sides of the tube, said elements being movable relatively in a direction toward and away from one another between tube pinching and tube releasing positions. Further, the structure also comprises a spring-loaded snap-action mechanism operably connected to at least one of the elements and actuatable for snapping said one element from one of said positions to the other. More specifically, the invention includes an overcenter device to provide the snap-action operation.
The invention is particularly directed to the provision of a switch of the kind described which is electrically normally open (that is to say, the tube is normally pinched and the liquid is normally parted). In this regard, the invention also includes, in its more specific aspects, means for pumping the liquid to momentarily increase its pressure at the instant of the snap-action release of the pinching elements whereby to cause the liquid to flow in a direction to form a continuous column to thereby close the electric circuit controlled by the switch.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side elevational view, partly in cross section, of
I an electrical switch embodying the principles and concepts of the instant invention;
FIG. 2 is a cross-sectional view of the switch taken substantially alongline 2--2 of FIG. 1;
FIG. 3 is a cross-sectional view of the switch taken substantially along line 3-3 of FIG. 1;
FIG. 4 is a side elevational view, partly in cross section, illustrating the tube-pinching elements of the switch in their tube-releasing position;
FIG. 5 is a side elevational view, partly in cross section, of another electrical switch which embodies the principles and concepts of the instant invention;
FIG. 6 is a cross-sectional view of the embodiment of FIG, 5 taken substantially along lines 6-6 ofFIG. 5;
FIG. 7 is a cross-sectional view of the embodiment of FIG. 5 taken substantially along lines 7-7 of FIG. 5; and
FIG. 8 is a side elevational view, partly in cross section, illustrating the two pinching elements of the switch embodiment of FIG. 5 in their tubereleasing position.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One form of an electrical switch, which embodies the concepts and principles of the instant invention is illustrated in FIGS. 1 4 and is designated therein by thenumeral 10. Switch 10 is of the type which is conventionally designated as being normally open. That is to say, in its normal, or at rest condition, the switch does not permit flow of electrical current between its contacts.
In its preferred form,switch 10 includes ahousing 12 which consists of amain body portion 14 and a lidportion l6v Portions 14 and 16 may be each formed in one piece from a moldable, thermoplastic resin such as, for example, polycarbonate resin. It is to be appreciated, however, that the material of construction ofportions 114 and 16 is not critical and other operable materials are well known to the routineer in this art.
Portion 14 includes ablock segment 18 and fourwalls 20, 22, 24 and 26 defining acavity 28.Lid portion 16 has asection 16a of reduced size which is completely surrounded by walls 20 -26 and forms a boundary forcavity 28 such that the latter is substantially completely enclosed.
A pair of spacedopenings 30 and 32 extend throughblock segment 18 to provide external access tocavity 28. Achannel 34, defined by a plurality ofwalls 36, 38 and 40 (see particularly FIG. 2), extends betweenopenings 30 and 32.
Viewing FIg. 3, it can be seen thatwalls 36 and 38 are each flared outwardly as at 36a and 38a to present awide spot 42 inchannel 34 disposed betweenopenings 32 and 30 and somewhat closer to the latter. Arib 44 extends transversely acrosschannel 34 atwide spot 42 for substantially the entire distance betweenwalls 22 and 26.Lateral walls 46 and 48 extend outwardly fromchannel 34 towalls 22 and 26 respectively and each includes an upwardly bowedsegment 50 disposed betweenwide spot 42 and opening 32. Thesegments 50 are preferably transversely hemispherical as can best be seen in FIG. l.
Atube 52 constructed of deformable and resilient material is positioned withinchannel 34. Tube 52 is preferably greater in diameter than the depth ofchannel 34 so that it protrudes slightly intocavity 28. Tube 52 is provided with anelectrical connector 54 at each end thereof and :is filled with an electrically conductive, nonwettingliquid 56, such as, for example, mercury.Connectors 54 may be substantially as shown in FIG. 1 to provide convenient means for electrically connecting the switch in a circuit and are well known in the art.Connectors 54 are disposed withinopenings 30 and 32 as shown, and asleeve 58 or the like may be provided forfastening tube 52 to eachconnector 54 and to substantially sealopenings 30 and 32 to thereby preclude entry of foreign materials intocavity 28.
Apost 60 extends inwardly ofcavity 28 fromsection 16a oflid portion 16.Post 60 is locatedadjacent opening 32 and the free end thereof protrudes slightly intochannel 34. A pair ofopposed abutments 62 are providedadjacent post 60. One of theabutments 62 extends inwardly fromwall 22 and upwardly fromwall 46, while theother abutment 62 extends inwardly fromwall 26 and upwardly from wall 48L An elongated, transversely bowed, cricket-type spring 64 has anopening 66 at one end thereof and alateral extension 68 disposed at the opposite end thereof.Spring 64 has a lateral width which is greater than the width ofchannel 34, but which is less than the width ofwide spot 42.Spring 64 is normally disposed with opening 66 receivingpost 60 therein and withextension 68adjacent rib 44 as shown in FIG. 1. It is to be particularly noted that the end ofspring 64adjacent post 60 is supported bywalls 46 and 48 and is positioned laterally betweenabutments 62 which operate to positionspring 64 centrally with respect tochannel 34.
Anopening 70 is provided inlid portion 16 and receives theshaft 72 of ashiftable pushbutton actuator 74 therethrough.
Actuator 74 includes ahead portion 76 disposed withincavity 28.Head portion 76 includes ashoulder 78 which is normally disposed against theinternal wall 80 oflid portion 16 to thereby limit the movement ofactuator 74 in a direction away fromtube 52.Head 76 is shaped to present anapex 82 which extends transversely ofspring 64 and normally contacts the same in transverse line contact.
As can be seen viewing FIG. 1,head portion 76 is of a size such that whenshoulder 78 is in contact withwall 80,tube 52 is pinched betweenextension 68 andrib 44. Thus, it can be said that the movable pinching element presented byextension 68 and the stationary pinching element presented by 44 are disposed in a tube-pinching position (or condition). With the switch in this condition, it can be seen that the same is normally open relative to flow of current betweenconnections 54. Also, in this condition, the force applied tospring 64 byapex 82 at the point of contact therebetween is sufficient to maintainextension 68 andrib 44 in their tube-pinching relationship, but is insufficient to flatten the transverse curvature ofspring 64 beyond its center, which would result in collapse of the spring. Further, in the condition illustrated in FIG. 1 thesegments 50 are preferably disposed in very slightly spaced relationship relative tospring 64, such that they can operate as fixed fulcrums immediately upon collapse ofspring 64 but do not interfere with the pinching of the tube when the switch is in its normally open position. Thus, it can be seen that switch includes structure operable for pinchingtube 52 to part the liquid 56 therein and open an electrical circuit.
Viewing FIG. 4, it can be seen that whenactuator 74 is pushed inwardly ofswitch 10, apex 82 will act' onspring 64 to flatten the same beyond the center point of its transverse curvature whereuponspring 64 will collapseadjacent apex 82. Immediately, the relativelyfixed end 84 ofspring 64 will flat ten againstwalls 46 and 48 while theopposite end 86 ofspring 64 will be pivoted about the fixed fulcrum presented by thesegments 50. Thus, theelements 44 and 68 will be rapidly shifted into a tube-releasing position.
Tube 52 is preferably constructed of a resilient and easily deformable material, such as latex rubber, neoprene rubber or butyl rubber or, for that matter, any type of rubber or elasticized material. More generally, any creep resistant material is satisfactory, so long as the same has good temperature resisting characteristics.
Thespring 64 and actuator .74 present a spring-loaded, snap-action mechanism for snappingelements 68 and 44 from their tube-pinching position into their tube-releasing position. The resiliency of the tube, which is provided by the material from which the same is constructed, assists in spreadingelements 68 and 44 apart. Thus, it can be said thattube 52 acts like a spring which is normally overpowered byspring 64 so long as the same is in its uncollapsed condition; however, the resiliency oftube 52 overpowersspring 64 after the same has been flattened beyond its overcenter or collapse point.
In addition to the normal operation of theswitch 10 as described above, switch 10'includes an additional capability which tends even more so to increase its responsiveness. Viewing FIG. 4, it can be seen thatactuator 74 has movedspring 64 into close contact withwalls 46 and 48. As discussed above,tube 52 has an outer diameter which is slightly greater than the depth ofchannel 34. Thus, whenspring 64 collapses,portion 84 ofspring 64 will pump liquid 56 towardelements 44 and 68 by exerting an instantaneous pressure ontube 52 along the entire length ofportion 84. This is best illustrated in FIG. 4 wherein it can be seen thatportion 84 has deflected the upper wall oftube 52.
It has been found with switches of this type that whenactuator 74 collapsesspring 64 and simultaneously pumps the fluid 56 withintube 52, an extremely fast response with no circuit bounce is achieved. In this regard, it has been found that theswitch 10 is capable of being cycled at a rate of 200 Hz. and has a contact rise time of less than one nanosecond.Switch 10 also provides operation with a mechanical movement of as little as 0.005 inch and with an actuation force of 3.2 ounces. Further, the switch has been found capable of handling a current of 50 milliamps at 24 volts DC with a contact resistance of 35 milliohms, whereby the switch is ideal for low energy circuits such as are found in digital computers and control applications.
Viewing FIG. 1, it can be seen thatswitch 10 may be provided with anadjustable screw 88 threadably engaged in anaperture 90.Screw 88 is provided with arounded head 92 disposed for compressingtube 52. Thus, the pressure withintube 52 may be increased whereby to tune the switch for particular operations. It is to be understood that thescrew 88 is normally not required even for extremely closely controlled operations. However, in applications which require the most extreme sensitivity, thescrew 88 may be included.
VIewing FIG. 4 Viewing FIG. 4, it can be seen thatswitch 10 may be provided with mountingholes 94 which extend throughblock segment 18.Holes 94 may preferably be of standardized size and disposition.
Another electrical switch which embodies the principles and concepts of the invention is illustrated in FIGS. 5 8 and is designated therein broadly by the numeral 110.Switch 110, likeswitch 10, is illustrated as being of the electrically normally open type. However, as will be explained later, switch may very simply be converted into an electrically normally closed type switch.
Switch 110 includes a housing 1l2 consisting of front andback portions 114 and 116, respectively,portions 114 and 116 are assembled, as illustrated particularly in FIGS. 6 and 7 and are rigidly held in mated relationship by screw means 118 and guide pins 120.
Housing 112 will generally be constructed of a thermoplastic material, such as polycarbonate resin, or the like. On the other hand,housing 112 could well be constructed of any material known in the art and could, for example, be machined from metal or even wood. In this regard, thermoplastic materials are generally utilized because they may be easily formed into intricate patterns.
Whenportions 114 and 116 are assembled as shown,housing 112 presents a vertical, rectangularly configuredchannel 122 which extends substantially entirely therethrough, except that it terminates in closely spaced relationship to theend 112a ofhousing 112. At approximately the center ofhousing 112, a pair of opposed laterally extendingcavities 124 communicate withchannel 122. The width ofcavities 124 is substantially less than the width ofchannel 122 as can best be seen by viewing FIG. 6A laterally extendingopening 126 extends from eachcavity 124 to the outside ofhousing 112.
An elongatedshiftable actuator 128 is disposed withinchannel 122.Actuator 128 includes anupper extremity 130, which extends outwardly ofhousing 112 and acoil spring 132 is disposed between thelowermost surface 134 ofactuator 128 and thebottom 136 ofchannel 122.
A vertically elongatedslot 138 extends throughactuator 128 and apin 140, which is anchored inhousing 112 is disposed withinslot 138. Thus, the vertical movement of actuator128 is limited by the interaction betweenslot 138 andpin 140.
Actuator 128 is provided with a hollowed outportion 142 defined by anupper wall 144, abackwall 146 and alower wall 148. Arib 150 extends upwardly fromwall 148 for a purpose to be described hereinbelow. A pair ofopposed extensions 152 extend forwardly fromwall 146 defining acentral groove 154 within hollowed outportion 142.
A deformableresilient tube 156 extends through hollowed outportion 142 aboveextensions 152.Tube 156 also extends laterally acrosscavities 124 as can best be seen in FIGS. 5 and 8.Tube 156 is preferably constructed of latex rubber, however neoprene rubber and butyl rubber or any type of rubber or elasticized material may also be used. Also, other deformable and resilient materials might also be utilized, so long as the same are substantially creep resistant and have good temperature resisting characteristics.Tube 56 is filled with an electrically conductive,nonwetting liquid 158, such as mercury or the like. Anelectrical connector 160 is provided at each end oftube 156.Connectors 160 are of the type well known to the routine'er in this art and are shaped to substantially completely fillopenings 126 to preclude entry of foreign materials into the internals ofhousing 112. Manifestly,connectors 160 are in electrically conducting contact withliquid 158.
A pinchingelement 162 is disposed betweenextensions 152 withingroove 154, and is slidable therein in a direction longitudinally ofactuator 128.Element 162 includes a wedge shaped pinching segment orhead 164 which presents an apex 166 disposed for contactingtube 156 in transverse line contact.
An elongated longitudinally bowedleaf spring 168 extends through hollowed outportion 142 beneathelement 162. As can be seen viewing FIGS. 5 and 8,spring 168 extends transversely ofchannel 122 and through each of thecavities 124. The ends 171) ofspring 168 are each anchored in a V-shapednotch 172 extending longitudinally of arod 174 anchored inhousing 112. Thus, each of theends 170 is relatively free to pivot at the apex ofits correspondingnotch 172.
Viewing FIG. 5, it can be seen thatspring 166 urgeselement 162 towardtube 156 andsurface 144 ofactuator 128. Thus,actuator 128 provides a pinching element leaving a pinchingsurface 144 which operates in cooperation with pinchingelement 162 for pinchingtube 156 therebetween topart liquid 158 and open an electric circuit. Thus, as illustrated in H0. 5, the tube-pinching elements are in a tube-pinching position. When an external force is applied to theupper extremity 130 ofactuator 128, the same is forced downwardly against the bias ofspring 132.Wall surface 144 pushes ontube 156, which in turn moveselement 162 downwardly against the bias ofspring 168. Whenspring 168 passes its overcenter point, the same will snap into an oppositely bowed condition to permitelement 162 to move away fromwall 144 andtube 156 to thereby assume a tube releasing position as illustrated in FIG. 8. Thus,switch 110 includes a spring-loaded, snap-action mechanism in the nature of an overcenter device for moving the pinching elements from their tube-pinching position into their tube-releasing position.
Upon release of the downward pressure on theextremity 130,spring 132 will urge actuator 128 upwardly. Rib 151) will movespring 168 upwardly until the latter passes its overcenter point, at which time it will snap upwardly into its upwardly bowed position. This will also snapelements 162 upwardly towardwall surface 144 to therebysnappingly pinch tube 156 and open the electrical circuit.
It can be seen that if the relative positions ofspring 132 and extremity 131) were reversed, the switch could be made to operate as a normally closed switch which snaps open, rather than a normally open switch which snaps closed as illustrated.
It is to be noted thatchannel 122 provides a path of travel for the pinching elements of switch 111 along which the elements are reciprocable. Further, theextensions 152 provide a guide structure for guiding the movement ofelement 162 along this path of travel.
It is to be particularly noted that the downward movement of thewall surface 144, which results from the application of an external force toextremity 130, exerts a pumping action ontube 156 which instantaneously slightly increases the pressure withintube 156 such that the fluid pressure within fluid 158 I will assist in the opening oftube 156 whenspring 168 snaps downwardly to move the elements into their tube-releasing position. This pumping action is caused by the pushing of the relativelylarge area surface 144 against the outer periphery oftube 156 to force the same downwardly into its U-shaped configuration as illustrated in FIG. 8.
Both of the switches described above provide a pumping action of the tube at the instant the pinching elements snap apart to thereby instantaneously increase the pressure of the electrically conductive fluid to assist the fluid in becoming a continuous column, so that the electrical circuit is thereby closed.
With this type of operation it is possible to obtain the benefits of a pressurized liquid system without the necessity for having the liquid maintained under pressure at all times while the switch is not in operation. That is to say, switches which embody the concepts and principles of this invention include tubes filled with electrically conductive fluid wherein the fluid is generally maintained at very nearly atmospheric pressure even during periods when the tube is pinched. On the other hand all of the benefits of a pressurized system are achieved since the elements act to pump the tube at the instant that the pinching elements snap apart.
Having thus described in detail several electrical switches which embody the concepts and principles of the invention, it should be appreciated and will be apparent to those skilled in the art that many physical changes could be made in the physical characteristics of the switches without altering the inventive principles and concepts embodied therein. Hence, it is intended that the scope of the invention be limited only to the extent indicated in the appended claims.
Iclaim:
1. A normally open circuit switch comprising:
a deformable tube filled with an electrically conductive liquid;
an actuator element having a pinching surface disposed adjacent said tube, said element being reciprocable along a path extending transversely of the tube and having a manually engageable portion remote from the tube and a guide on the opposite side of the tube from said manually engageable portion; pinching head disposed on the opposite side of the tube from said pinching surface, said head being slideably mounted in said guide to be recipzrocable along said path, said head including a pinching segment presenting an apex extending transversely of the tube for engaging the tube in transverse line contact;
an elongated longitudinally bowed leaf spring operably engaged with said head and extending transversely of said path, said spring extending adjacent the guide on the opposite side of the head from said tube, said spring being normally bowed in one direction along the path for urging the head in said direction to pinch said tube against said pinching surface and being bowed in the opposite direction along said path in response to movement of said pinching surface for permitting movement of said head in the opposite direction; and 7 return spring means operably engaging the actuator element and urging said actuator element in said one direction.
2. A switch comprising:
a deformable tube filled with an electrically conductive liquid;
a stationary pinching element disposed adjacent said tube;
an elongated cricket spring member which is normally transversely bowed throughout its length, said spring member including a second pinching element located at one end thereof, said spring member being disposed with said second pinching element located adjacent said tube on the opposite side thereof from said stationary pinching element, the opposite end of said spring member being relatively fixed in a position urging the second pinching element toward the stationary pinching element to pinch the tube therebetween and part said liquid;
21 pushbutton actuator having an apex engageable with the transverse bow of said spring member for collapsing the same to permit separation of the pinching elements and release said tube; and
fulcrum means disposed between said second pinching element and said apex of said pushbutton actuator in a position supporting said spring member and causing said second pinching element to rapidly pivot about said fulcrum means upon collapse of said spring member.
3. Structure as set forth inclaim 2, wherein is included tubecompressing mechanism for changing the pressure of the liquid in the tube to obtain different operation in response to movement of said actuator.
4. Structure as set forth inclaim 3, wherein said compressing mechanism includes an adjustable screw device.
5. A switch as set forth inclaim 2, wherein a portion of the spring is movable into pressure-applying relationship relative to said tube after collapse of said spring whereby to increase the pressure of the fluid in the tube to assist the opening of the same after it is released by the elements.
6. A switch comprising:
a housing;
a deformable tube filled with an electrically conductive liquid mounted within said housing;
structure operable to pinch said tube to part the liquid and open an electrical circuit including a pair of spaced 7 pinching elements disposed on opposite sides of the tube, said elements being movable relatively in a direction toward and away from one another between tube pinching and tube-releasing positions;
spring-loaded snap-action mechanism operably connected to at least one of the elements and actuatable to snap said one element from one of said positions to the other;
an overcenter device forming a part of said mechanism including an elongated bowed spring having at least one end fixed relative to said housing and a portion of said spring remote from said fixed end engaging said one element with said tube in said tube-pinching position;
an actuator movably mounted relative to said housing and disposed relative to the bow of said spring to engage and deflect said bow upon movement of said actuator and thereby snap said one element from one of said positions to the other; and
means for instantaneously increasing the pressure of the liquid in the tube at the moment the one element is shifted into said releasing position.

Claims (6)

1. A normally open circuit switch comprising: a deformable tube filled with an electrically conductive liquid; an actuator element having a pinching surface disposed adjacent said tube, said element being reciprocable along a path extending transversely of the tube and having a manually engageable portion remote from the tube and a guide on the opposite side of the tube from said manually engageable portion; a pinching head disposed on the opposite side of the tube from said pinching surface, said head being slideably mounted in said guide to be reciprocable along said path, said head including a pinching segment presenting an apex extending transversely of the tube for engaging the tube in transverse line contact; an elongated longitudinally boweD leaf spring operably engaged with said head and extending transversely of said path, said spring extending adjacent the guide on the opposite side of the head from said tube, said spring being normally bowed in one direction along the path for urging the head in said direction to pinch said tube against said pinching surface and being bowed in the opposite direction along said path in response to movement of said pinching surface for permitting movement of said head in the opposite direction; and return spring means operably engaging the actuator element and urging said actuator element in said one direction.
2. A switch comprising: a deformable tube filled with an electrically conductive liquid; a stationary pinching element disposed adjacent said tube; an elongated cricket spring member which is normally transversely bowed throughout its length, said spring member including a second pinching element located at one end thereof, said spring member being disposed with said second pinching element located adjacent said tube on the opposite side thereof from said stationary pinching element, the opposite end of said spring member being relatively fixed in a position urging the second pinching element toward the stationary pinching element to pinch the tube therebetween and part said liquid; a pushbutton actuator having an apex engageable with the transverse bow of said spring member for collapsing the same to permit separation of the pinching elements and release said tube; and fulcrum means disposed between said second pinching element and said apex of said pushbutton actuator in a position supporting said spring member and causing said second pinching element to rapidly pivot about said fulcrum means upon collapse of said spring member.
6. A switch comprising: a housing; a deformable tube filled with an electrically conductive liquid mounted within said housing; structure operable to pinch said tube to part the liquid and open an electrical circuit including a pair of spaced pinching elements disposed on opposite sides of the tube, said elements being movable relatively in a direction toward and away from one another between tube pinching and tube-releasing positions; spring-loaded snap-action mechanism operably connected to at least one of the elements and actuatable to snap said one element from one of said positions to the other; an overcenter device forming a part of said mechanism including an elongated bowed spring having at least one end fixed relative to said housing and a portion of said spring remote from said fixed end engaging said one element with said tube in said tube-pinching position; an actuator movably mounted relative to said housing and disposed relative to the bow of said spring to engage and deflect said bow upon movement of said actuator and thereby snap said one element from one of said positions to the other; and means for instantaneously increasing the pressure of the liquid in the tube at the moment the one element is shifted into said releasing position.
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US20040188234A1 (en)*2003-03-312004-09-30Dove Lewis R.Hermetic seal and controlled impedance rf connections for a liquid metal micro switch
US20040201319A1 (en)*2003-04-142004-10-14Wong Marvin GlennHigh frequency push-mode latching relay
US20040201311A1 (en)*2003-04-142004-10-14Wong Marvin GlennHigh frequency bending-mode latching relay
US20040202404A1 (en)*2003-04-142004-10-14Wong Marvin GlennPolymeric liquid metal optical switch
US20040201320A1 (en)*2003-04-142004-10-14Carson Paul ThomasInserting-finger liquid metal relay
US20040202844A1 (en)*2003-04-142004-10-14Wong Marvin GlennFeature formation in thick-film inks
US20040202411A1 (en)*2003-04-142004-10-14Wong Marvin GlennMethod and structure for a pusher-mode piezoelectrically actuated liquid metal optical switch
US20040200708A1 (en)*2003-04-142004-10-14Wong Marvin GlennMethod and structure for a slug assisted pusher-mode piezoelectrically actuated liquid metal optical switch
US20040201318A1 (en)*2003-04-142004-10-14Wong Marvin GlenLatching relay with switch bar
US20040201440A1 (en)*2003-04-142004-10-14Arthur FongLongitudinal electromagnetic latching relay
US20040202408A1 (en)*2003-04-142004-10-14Wong Marvin GlennPressure actuated optical latching relay
US20040200704A1 (en)*2003-04-142004-10-14Arthur FongFluid-based switch
US20040202558A1 (en)*2003-04-142004-10-14Arthur FongClosed-loop piezoelectric pump
US20040201329A1 (en)*2003-04-142004-10-14Wong Marvin GlennDamped longitudinal mode latching relay
US20040201907A1 (en)*2003-04-142004-10-14Wong Marvin GlennLiquid metal optical relay
US20040201317A1 (en)*2003-04-142004-10-14Wong Marvin GlennMethod and structure for a pusher-mode piezoelectrically actuated liquid switch metal switch
US20040202414A1 (en)*2003-04-142004-10-14Wong Marvin GlennReflecting wedge optical wavelength multiplexer/demultiplexer
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US20040201906A1 (en)*2003-04-142004-10-14Wong Marvin GlennLongitudinal mode solid slug optical latching relay
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US20040201330A1 (en)*2003-04-142004-10-14Arthur FongMethod and apparatus for maintaining a liquid metal switch in a ready-to-switch condition
US20040200705A1 (en)*2003-04-142004-10-14Wong Marvin GlennFormation of signal paths to increase maximum signal-carrying frequency of a fluid-based switch
US20040201313A1 (en)*2003-04-142004-10-14Wong Marvin GlennHigh-frequency, liquid metal, latching relay with face contact
US20040201322A1 (en)*2003-04-142004-10-14Wong Marvin GlennLongitudinal mode optical latching relay
US20040201312A1 (en)*2003-04-142004-10-14Arthur FongMethod and structure for a slug assisted longitudinal piezoelectrically actuated liquid metal optical switch
US20040201323A1 (en)*2003-04-142004-10-14Wong Marvin GlennShear mode liquid metal switch
US20040202413A1 (en)*2003-04-142004-10-14Wong Marvin GlennMethod and structure for a solid slug caterpillar piezoelectric optical relay
US20040201315A1 (en)*2003-04-142004-10-14Wong Marvin GlennBending-mode latching relay
US20040201316A1 (en)*2003-04-142004-10-14Arthur FongMethod and structure for a solid slug caterpillar piezoelectric relay
US20040200702A1 (en)*2003-04-142004-10-14Arthur FongPush-mode latching relay
US20040200706A1 (en)*2003-04-142004-10-14Dove Lewis R.Substrate with liquid electrode
US20040201321A1 (en)*2003-04-142004-10-14Wong Marvin GlennHigh frequency latching relay with bending switch bar
US20040200703A1 (en)*2003-04-142004-10-14Wong Marvin GlennBending mode liquid metal switch
US20040251117A1 (en)*2003-06-162004-12-16Wong Marvin GlennSuspended thin-film resistor
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US6927529B2 (en)2002-05-022005-08-09Agilent Technologies, Inc.Solid slug longitudinal piezoelectric latching relay
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US20040112727A1 (en)*2002-12-122004-06-17Wong Marvin GlennLaser cut channel plate for a switch
US20040112729A1 (en)*2002-12-122004-06-17Wong Marvin GlennSwitch and method for producing the same
US20040112726A1 (en)*2002-12-122004-06-17Wong Marvin GlennUltrasonically milled channel plate for a switch
US20040112724A1 (en)*2002-12-122004-06-17Wong Marvin GlennVolume adjustment apparatus and method for use
US7022926B2 (en)2002-12-122006-04-04Agilent Technologies, Inc.Ultrasonically milled channel plate for a switch
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US6774324B2 (en)2002-12-122004-08-10Agilent Technologies, Inc.Switch and production thereof
US6924444B2 (en)2002-12-122005-08-02Agilent Technologies, Inc.Ceramic channel plate for a fluid-based switch, and method for making same
US6849144B2 (en)2002-12-122005-02-01Agilent Technologies, Inc.Method for making switch with ultrasonically milled channel plate
US6855898B2 (en)2002-12-122005-02-15Agilent Technologies, Inc.Ceramic channel plate for a switch
US6909059B2 (en)2002-12-122005-06-21Agilent Technologies, Inc.Liquid switch production and assembly
US6743990B1 (en)2002-12-122004-06-01Agilent Technologies, Inc.Volume adjustment apparatus and method for use
US20050051412A1 (en)*2002-12-122005-03-10Wong Marvin GlennCeramic channel plate for a fluid-based switch, and method for making same
US7098413B2 (en)2003-01-132006-08-29Agilent Technologies, Inc.Photoimaged channel plate for a switch, and method for making a switch using same
US6897387B2 (en)2003-01-132005-05-24Agilent Technologies, Inc.Photoimaged channel plate for a switch
US20050126899A1 (en)*2003-01-132005-06-16Wong Marvin G.Photoimaged channel plate for a switch, and method for making a switch using same
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US6911611B2 (en)2003-01-222005-06-28Agilent Technologies, Inc.Method for registering a deposited material with channel plate channels
US6809277B2 (en)2003-01-222004-10-26Agilent Technologies, Inc.Method for registering a deposited material with channel plate channels, and switch produced using same
US6747222B1 (en)2003-02-042004-06-08Agilent Technologies, Inc.Feature formation in a nonphotoimagable material and switch incorporating same
US20040188234A1 (en)*2003-03-312004-09-30Dove Lewis R.Hermetic seal and controlled impedance rf connections for a liquid metal micro switch
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US20040201322A1 (en)*2003-04-142004-10-14Wong Marvin GlennLongitudinal mode optical latching relay
US6903493B2 (en)2003-04-142005-06-07Agilent Technologies, Inc.Inserting-finger liquid metal relay
US20040202844A1 (en)*2003-04-142004-10-14Wong Marvin GlennFeature formation in thick-film inks
US20040202411A1 (en)*2003-04-142004-10-14Wong Marvin GlennMethod and structure for a pusher-mode piezoelectrically actuated liquid metal optical switch
US20040200708A1 (en)*2003-04-142004-10-14Wong Marvin GlennMethod and structure for a slug assisted pusher-mode piezoelectrically actuated liquid metal optical switch
US20040201318A1 (en)*2003-04-142004-10-14Wong Marvin GlenLatching relay with switch bar
US20040201440A1 (en)*2003-04-142004-10-14Arthur FongLongitudinal electromagnetic latching relay
US20040202408A1 (en)*2003-04-142004-10-14Wong Marvin GlennPressure actuated optical latching relay
US20040200704A1 (en)*2003-04-142004-10-14Arthur FongFluid-based switch
US20040202558A1 (en)*2003-04-142004-10-14Arthur FongClosed-loop piezoelectric pump
US20040201329A1 (en)*2003-04-142004-10-14Wong Marvin GlennDamped longitudinal mode latching relay
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US20040201317A1 (en)*2003-04-142004-10-14Wong Marvin GlennMethod and structure for a pusher-mode piezoelectrically actuated liquid switch metal switch
US20040202414A1 (en)*2003-04-142004-10-14Wong Marvin GlennReflecting wedge optical wavelength multiplexer/demultiplexer
US20040200707A1 (en)*2003-04-142004-10-14Wong Marvin GlennBent switching fluid cavity
US20040201906A1 (en)*2003-04-142004-10-14Wong Marvin GlennLongitudinal mode solid slug optical latching relay
US20040202410A1 (en)*2003-04-142004-10-14Wong Marvin GlennLongitudinal electromagnetic latching optical relay
US20040201309A1 (en)*2003-04-142004-10-14Wong Marvin GlennInsertion-type liquid metal latching relay array
US20040201314A1 (en)*2003-04-142004-10-14Wong Marvin GlennWetting finger latching piezoelectric relay
US20040202412A1 (en)*2003-04-142004-10-14Wong Marvin GlennPressure actuated solid slug optical latching relay
US20040201310A1 (en)*2003-04-142004-10-14Wong Marvin GlennDamped longitudinal mode optical latching relay
US20040201330A1 (en)*2003-04-142004-10-14Arthur FongMethod and apparatus for maintaining a liquid metal switch in a ready-to-switch condition
US20040200705A1 (en)*2003-04-142004-10-14Wong Marvin GlennFormation of signal paths to increase maximum signal-carrying frequency of a fluid-based switch
US20040201313A1 (en)*2003-04-142004-10-14Wong Marvin GlennHigh-frequency, liquid metal, latching relay with face contact
US20040202404A1 (en)*2003-04-142004-10-14Wong Marvin GlennPolymeric liquid metal optical switch
US20040201312A1 (en)*2003-04-142004-10-14Arthur FongMethod and structure for a slug assisted longitudinal piezoelectrically actuated liquid metal optical switch
US20040201323A1 (en)*2003-04-142004-10-14Wong Marvin GlennShear mode liquid metal switch
US20040202413A1 (en)*2003-04-142004-10-14Wong Marvin GlennMethod and structure for a solid slug caterpillar piezoelectric optical relay
US20040201315A1 (en)*2003-04-142004-10-14Wong Marvin GlennBending-mode latching relay
US20040201316A1 (en)*2003-04-142004-10-14Arthur FongMethod and structure for a solid slug caterpillar piezoelectric relay
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