US2305717A - Circuit controlling means - Google Patents

Circuit controlling means Download PDF

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US2305717A
US2305717A US300870A US30087039A US2305717A US 2305717 A US2305717 A US 2305717A US 300870 A US300870 A US 300870A US 30087039 A US30087039 A US 30087039A US 2305717 A US2305717 A US 2305717A
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pad
circuit controlling
current conducting
carbon
current
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US300870A
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Bell Oidric Joseph La
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01CRESISTORS
    • H01C10/00Adjustable resistors
    • H01C10/10Adjustable resistors adjustable by mechanical pressure or force
    • H01C10/106Adjustable resistors adjustable by mechanical pressure or force on resistive material dispersed in an elastic material

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  • the principal object of my invention is to provide a circuit controlling means adapted to be actuated by static or impact loads.
  • Another object of the invention is to provide a' device for measuringor indicating the magnitude of static or impact loads.
  • My invention relates more particularly to a pressure-responsive circuit controlling means and provides an elastic cellular, or porous and nonconductive medium which is made into a conductor of variable conductivity by filling the cells or pores with a powdered conductive material.
  • I have taken a fine grade of highly porous sponge rubber and filled the voids or cells therein with powdered carbon.
  • Sponge rubber is, of course, a highly elastic material and also a good insulator. Its pores can accommodate a high percentage, by volume, of powdered carbon. The grains of carbon are also sufficiently elastic and are excellent conductors.
  • the elastic carbon pad it can hardly be called a pile, is then ready to act as an insulator or as a conductor depending entirely upon the amount of pressure to which it is subjected. This, of course, depends upon the amount of carbon present and the voltage applied. However a small pad two inches in diameter and a half inch thick when submitted to a potential of 45 volts D. C. will pass no current if free from outside pressure. As the pressure is increased the flow of current begins and varies with the intensity To illustrate the actual working of this principle, I have attached hereto several drawings of different applications or uses.
  • Figure l is a cross-sectional view through a strip of circuit controlling material constructed in accordance with the principles of the present invention.
  • Figure 2 is a diagrammatic cross-sectional view of a device adapted to indicate the magnitude 55 of static or impact loads and embodying the principles of the present invention.
  • Figure 3 is a cross-sectional view through a sealed circuit controlling unit such as employed in the device shown in Figure 2, but with conductor wires connected to the plates of the unit so that it can be used, 'if desired, without the piston and cylinder shown in Figure 2.
  • FIG 1 I have shown in cross section a simple embodiment that can serve as a circuit controlling means associated with a roadway, etc., designed to be actuated by a vehicle wheel passing over it or by a person stepping upon it.
  • Figure 1 is a rubber casing or housing which protects the circuit controlling element
  • the circuit controlling element consists of the two conductors 2 and 4 separated by the continuous strip of sponge rubber, '3, impregnated with carbon as previously described. A vehicle wheel passing over the device would compress the sponge rubber, 3, and the incorporated carbon granules permitting a current to flow from conductor 2 This current may then be used to actuate diverse types of electrical from wear and tear and weather.
  • Ill is a cylinder made of a nonconductive material preferably hard rubber or
  • Number II is a metal piston including a portion ll designed to slide vertically within the cylindrical walls of cylinder l0 and serve as
  • the piston Ii has an annular recess [2 to receive the side wall
  • Number I3 is a disc shaped carbon pad and number [4 is the metal bottom of the cylinder and the second of the pair of conductors.
  • Conductors -II and ii are placed in series with a simple electrical direct current circuit including a battery I5 and an ammeter i6.
  • Plates Ill and I8 are suitably attached to the opposite sides of the pad i3 and the periphery or side wall of said pad is sealed by a suitable elastic cement l9 to retain the carbon particles 20 within said pad. From previous tests with known weights and known pressures applied to the weigh platform portion 2 I, the relation between amperes and pounds is determined for the particular pad in question and the dial of the ammeter is preferably calibrated in pounds weight to give a Bakelite.
  • the piston, l l moves downward compressing the carbon pad, I3, and decreasing its internal resistance and thereby increasing the reading on the ammeter scale, IS.
  • the needle 22 of the ammeter I6 is moved according to the load applied and the ammeter scale is read when said needle comes to rest and this reading will be the weight in pounds.
  • Figure 3 shows a circuit controlling pad or unit of the type used in the device shown in Figure 2 but with conductor wires 23 and 24 secured directly to the plates l1 and 18, respectively.
  • the 'I'he sponge-rubber carbon-impregnated pad of my invention can also be made as follows: the disc or body to be impregnated is placed in the bottom outlet neck of a tank (not shown) into which is placed, under pressure, a mixture of powdered carbon and water. This mixture is continually agitated so that the carbon particles are suspended throughout the liquid in a state approximating a colloidal suspension. This mixture is then filtered through the sponge pad where the particles of carbon tend to accumulate in the cells, or pores, of the pad. After a certain period the predetermined amount of carbon has been deposited in the pad the flow is stopped and the pad is removed and allowed to dry. To the dry pad are attached the top and bottom conductors. The carbon pad is then tested and calibrated after which it is ready for use.
  • Circuit controlling means comprising two substantially flat current conducting elements; a flat, resilient, integral body of cellular non-conducting material attached to said conducting elements and separating said conducting elements, the area of the adjacent contacting surfaces of said fiat conducting elements and said body being substantially equal; a finely divided conducting material substantially completely filling the cells of said flat body, said attached plates serving as sealing means to retain said material in said cellular body; and housing means enclosing said flat conducting elements and said flat body.
  • a circuit controlling unit comprising two thin, disc-shaped conductor elements; a homogeneous relatively thick circular body of cellular elastic sponge rubber separating said conductor elements and constituting the sole means for maintaining said conductor elements 'in spaced apart relation, said conductor elements and said body being of substantially the same diameter; a powdered conducting material substantially completely permeating the cells of said body; and elastic means adhering to and sealing the peripheral surface of said cellular body to retain said powdered conducting material therein, said disc-shaped conductor elements being attached to said cellular body to further retain said powdered material therein.
  • Means for use in an electrical circuit comprising a resilient body of porous non-conducting'material; a powdered conducting material substantially completely permeating the pores of said body; and means adhering to and sealing the peripheral surface of said porous body to retain said powdered material therein.
  • Means for use in an electrical circuit comprising a body of sponge rubber of substantial thickness; particles of finely divided carbon substantially uniformly distributed throughout the voids of said body; and an elastic medium adhering to and sealing the side walls of said body to retain said powdered carbon therein.
  • Circuit controlling means comprising, two current conducting elements; a body of resilient, cellular non-conducting material separating said conducting elements; a powdered conducting material substantially completely permeating the cells of said body; and means adhering to and sealing the peripheral surface of said cellular body to retain said powdered material therein.
  • Circuit controlling means comprising two current conducting plates, 8. yieldable body of porous non-conducting material interposed between said plates; a powdered conducting material substantially completely permeating the cells of said body; means attaching said plates to the .top and bottom surfaces of said body; and means sealing the side surface of said porous body to retain said powdered material therein.
  • a circuit controlling device comprising a hollow member; a current conducting element carried by one end of said hollow member; a second current conducting element being arranged for unrestrained movement in opposite. directions in said hollow member; and a body oi! elastic porous non-conducting material in said hollow member interposed between said current conducting elements and being adapted to be compressed in accordance with the force acting upon said second current conducting element and to return to its initial uncompressed state upon withdrawal of said force, said body having the pores thereof substantially completely permeated with a finely divided conducting material and means for sealing the peripheral surface of said porous elastic body to retain said conducting material therein.
  • a circuit controlling device comprising a hollow member of insulating material; a current conducting element carried by one end of said hollow member; a second current conducting element adapted to have a force act thereon, said second current conducting element being arranged for unrestrained movement in opposite directions relative to said first current conducting element; a body of yieldable cellular nonconducting material interposed between said current conducting elements and being adapted to be compressed in accordance with the force acting upon said second current conducting element and to return to its uncompressed state upon withdrawal of said force, said body having the cells thereof substantially completely permeated with grains of a current conducting material; a metal plate disposed between said body and each of said current conducting elements; and elastic means adhering to and sealing the peripheral surface of said body, said plates being attached to said body and serving to prevent escape of said current-conducting material therefrom.
  • Circuit controlling means comprising a hollow member; a current conducting element adjacent to one end of said hollow member; a second current conducting element adapted to have a force act thereon, said second current conducting element having a portion telescoping said hollow member and being arranged for movement relative to said hollow member and to said first current conductingelement; and a body .of resilient cellular non-conducting material interposed between said current conducting elements and being adapted to be compressed in aoordance with the force acting upon'said second current conducting element, said body having the cells thereof substantially completely permeated with a powdered current conducting material.
  • Circuit controlling means comprising a hollow member; a current conducting element adjacent to one end of said hollow member; a sec- 0nd current conducting element arranged for movement relative to said first current conducting element and being adapted to have a force act thereon; a body of non-fibrous resilient cellular non-conducting material in said hollow member interposed between said current conducting elements and being adapted to be compressed in accordance with the force acting upon said second current conducting element and to return to its initial uncompressed state uponwithdrawal of said force, said body having the cells thereof substantially completely permeated with a finely divided current conducting material; and means cooperable with one of said current conducting elements and in telescoping engagement with the other of said current conducting elements for maintaining said current conducting elements in substantial parallelism at all times.

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  • Chemical & Material Sciences (AREA)
  • Dispersion Chemistry (AREA)
  • Engineering & Computer Science (AREA)
  • Microelectronics & Electronic Packaging (AREA)
  • Investigating Or Analyzing Materials By The Use Of Electric Means (AREA)

Description

' Dec. 22, 1942. o. J. LA BELL 2,305,717
CIRCUIT CONTROLLING MEANS F iled Oct. 23, 1939 AII I I I I M gnaw/whom- Uldric ZaBeZZ of pressure.
Patented Dec. 22,1942
Oldrlc Joseph La Bell, Washington, D. 0.
Application October 23, 1939, Serial No. 300,870
Claims.
The principal object of my invention is to provide a circuit controlling means adapted to be actuated by static or impact loads.
Another object of the invention is to provide a' device for measuringor indicating the magnitude of static or impact loads.
My invention relates more particularly to a pressure-responsive circuit controlling means and provides an elastic cellular, or porous and nonconductive medium which is made into a conductor of variable conductivity by filling the cells or pores with a powdered conductive material. Thus to accomplish this result I have taken a fine grade of highly porous sponge rubber and filled the voids or cells therein with powdered carbon. These materials are by no means the only ones that lend themselves to this end but they are everyday materials easily obtainable to demonstrate the invention.
Sponge rubber is, of course, a highly elastic material and also a good insulator. Its pores can accommodate a high percentage, by volume, of powdered carbon. The grains of carbon are also sufficiently elastic and are excellent conductors.
In making this carbon pad, I take a disc or body of sponge rubber and pour into slits of the side wall and into the top and bottom faces, finely ground powdered carbon. When the proper amount of carbon has been incorporated within the cells and uniformly distributed therein, I seal the side walls with an elastic cement and. attach to the top and bottom faces of the pad, metal plates or discs. These discs serve as the positive and negative conductors.
The elastic carbon pad, it can hardly be called a pile, is then ready to act as an insulator or as a conductor depending entirely upon the amount of pressure to which it is subjected. This, of course, depends upon the amount of carbon present and the voltage applied. However a small pad two inches in diameter and a half inch thick when submitted to a potential of 45 volts D. C. will pass no current if free from outside pressure. As the pressure is increased the flow of current begins and varies with the intensity To illustrate the actual working of this principle, I have attached hereto several drawings of different applications or uses.
Figure l is a cross-sectional view through a strip of circuit controlling material constructed in accordance with the principles of the present invention;
Figure 2 is a diagrammatic cross-sectional view of a device adapted to indicate the magnitude 55 of static or impact loads and embodying the principles of the present invention; and
Figure 3 is a cross-sectional view through a sealed circuit controlling unit such as employed in the device shown in Figure 2, but with conductor wires connected to the plates of the unit so that it can be used, 'if desired, without the piston and cylinder shown in Figure 2.
In Figure 1, I have shown in cross section a simple embodiment that can serve as a circuit controlling means associated with a roadway, etc., designed to be actuated by a vehicle wheel passing over it or by a person stepping upon it. In Figure 1, number I, is a rubber casing or housing which protects the circuit controlling element The circuit controlling element consists of the two conductors 2 and 4 separated by the continuous strip of sponge rubber, '3, impregnated with carbon as previously described. A vehicle wheel passing over the device would compress the sponge rubber, 3, and the incorporated carbon granules permitting a current to flow from conductor 2 This current may then be used to actuate diverse types of electrical from wear and tear and weather.
through 3 and into 4.
mechanisms.
In Figure 2, I make use, in a very simple manher, of that property of the pad that permits the current flowing through it to vary with the pressure exerted upon the two parallel faces of the pad. Thus Ill, is a cylinder made of a nonconductive material preferably hard rubber or Number II is a metal piston including a portion ll designed to slide vertically within the cylindrical walls of cylinder l0 and serve as The piston Ii has an annular recess [2 to receive the side wall Number I3 is a disc shaped carbon pad and number [4 is the metal bottom of the cylinder and the second of the pair of conductors. Conductors -II and ii are placed in series with a simple electrical direct current circuit including a battery I5 and an ammeter i6. Plates Ill and I8 are suitably attached to the opposite sides of the pad i3 and the periphery or side wall of said pad is sealed by a suitable elastic cement l9 to retain the carbon particles 20 within said pad. From previous tests with known weights and known pressures applied to the weigh platform portion 2 I, the relation between amperes and pounds is determined for the particular pad in question and the dial of the ammeter is preferably calibrated in pounds weight to give a Bakelite.
the first of a pair of conductors.
of the cylinder I0.
direct reading.
Thus when an unknown weight is applied to the platform portion ill, the piston, l l, moves downward compressing the carbon pad, I3, and decreasing its internal resistance and thereby increasing the reading on the ammeter scale, IS. The needle 22 of the ammeter I6 is moved according to the load applied and the ammeter scale is read when said needle comes to rest and this reading will be the weight in pounds.
Figure 3 shows a circuit controlling pad or unit of the type used in the device shown in Figure 2 but with conductor wires 23 and 24 secured directly to the plates l1 and 18, respectively.
It is to be realized, of course, that what I have shown here is the very simplest type of an electrical scale. For special operations such as weighing the load on axles of vehicles, it may be necessary to use an entire battery of these pressure cells in conjunction with more complicated control apparatus.
Due to the inherent structure of this pad it is especially adapted to the measuring of rapid and momentary applications of force without the danger of damaging the pad itself. Thus, the impact of moving wheel loads can be determined as can also the value of static wheel loads.
While I have described the pad as being essentially a disc, this is not an essential part of the invention. An oblong pad or one of irregular outline can be made to serve equally well.
'I'he sponge-rubber carbon-impregnated pad of my invention can also be made as follows: the disc or body to be impregnated is placed in the bottom outlet neck of a tank (not shown) into which is placed, under pressure, a mixture of powdered carbon and water. This mixture is continually agitated so that the carbon particles are suspended throughout the liquid in a state approximating a colloidal suspension. This mixture is then filtered through the sponge pad where the particles of carbon tend to accumulate in the cells, or pores, of the pad. After a certain period the predetermined amount of carbon has been deposited in the pad the flow is stopped and the pad is removed and allowed to dry. To the dry pad are attached the top and bottom conductors. The carbon pad is then tested and calibrated after which it is ready for use.
On the basis of the disclosures in the foregoing specifications, I claim as my inventionthe following:
1. Circuit controlling means comprising two substantially flat current conducting elements; a flat, resilient, integral body of cellular non-conducting material attached to said conducting elements and separating said conducting elements, the area of the adjacent contacting surfaces of said fiat conducting elements and said body being substantially equal; a finely divided conducting material substantially completely filling the cells of said flat body, said attached plates serving as sealing means to retain said material in said cellular body; and housing means enclosing said flat conducting elements and said flat body.
2. A circuit controlling unit comprising two thin, disc-shaped conductor elements; a homogeneous relatively thick circular body of cellular elastic sponge rubber separating said conductor elements and constituting the sole means for maintaining said conductor elements 'in spaced apart relation, said conductor elements and said body being of substantially the same diameter; a powdered conducting material substantially completely permeating the cells of said body; and elastic means adhering to and sealing the peripheral surface of said cellular body to retain said powdered conducting material therein, said disc-shaped conductor elements being attached to said cellular body to further retain said powdered material therein.
3. Means for use in an electrical circuit comprising a resilient body of porous non-conducting'material; a powdered conducting material substantially completely permeating the pores of said body; and means adhering to and sealing the peripheral surface of said porous body to retain said powdered material therein.
4. Means for use in an electrical circuit comprising a body of sponge rubber of substantial thickness; particles of finely divided carbon substantially uniformly distributed throughout the voids of said body; and an elastic medium adhering to and sealing the side walls of said body to retain said powdered carbon therein.
5. Circuit controlling means comprising, two current conducting elements; a body of resilient, cellular non-conducting material separating said conducting elements; a powdered conducting material substantially completely permeating the cells of said body; and means adhering to and sealing the peripheral surface of said cellular body to retain said powdered material therein.
6. Circuit controlling means comprising two current conducting plates, 8. yieldable body of porous non-conducting material interposed between said plates; a powdered conducting material substantially completely permeating the cells of said body; means attaching said plates to the .top and bottom surfaces of said body; and means sealing the side surface of said porous body to retain said powdered material therein.
'7. A circuit controlling device comprising a hollow member; a current conducting element carried by one end of said hollow member; a second current conducting element being arranged for unrestrained movement in opposite. directions in said hollow member; and a body oi! elastic porous non-conducting material in said hollow member interposed between said current conducting elements and being adapted to be compressed in accordance with the force acting upon said second current conducting element and to return to its initial uncompressed state upon withdrawal of said force, said body having the pores thereof substantially completely permeated with a finely divided conducting material and means for sealing the peripheral surface of said porous elastic body to retain said conducting material therein.
8. A circuit controlling device comprising a hollow member of insulating material; a current conducting element carried by one end of said hollow member; a second current conducting element adapted to have a force act thereon, said second current conducting element being arranged for unrestrained movement in opposite directions relative to said first current conducting element; a body of yieldable cellular nonconducting material interposed between said current conducting elements and being adapted to be compressed in accordance with the force acting upon said second current conducting element and to return to its uncompressed state upon withdrawal of said force, said body having the cells thereof substantially completely permeated with grains of a current conducting material; a metal plate disposed between said body and each of said current conducting elements; and elastic means adhering to and sealing the peripheral surface of said body, said plates being attached to said body and serving to prevent escape of said current-conducting material therefrom.
9. Circuit controlling means comprising a hollow member; a current conducting element adjacent to one end of said hollow member; a second current conducting element adapted to have a force act thereon, said second current conducting element having a portion telescoping said hollow member and being arranged for movement relative to said hollow member and to said first current conductingelement; and a body .of resilient cellular non-conducting material interposed between said current conducting elements and being adapted to be compressed in aoordance with the force acting upon'said second current conducting element, said body having the cells thereof substantially completely permeated with a powdered current conducting material.
10. Circuit controlling means comprising a hollow member; a current conducting element adjacent to one end of said hollow member; a sec- 0nd current conducting element arranged for movement relative to said first current conducting element and being adapted to have a force act thereon; a body of non-fibrous resilient cellular non-conducting material in said hollow member interposed between said current conducting elements and being adapted to be compressed in accordance with the force acting upon said second current conducting element and to return to its initial uncompressed state uponwithdrawal of said force, said body having the cells thereof substantially completely permeated with a finely divided current conducting material; and means cooperable with one of said current conducting elements and in telescoping engagement with the other of said current conducting elements for maintaining said current conducting elements in substantial parallelism at all times.
OLDRIC JOSEPH LA BELL.
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Cited By (23)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2445660A (en) * 1945-08-17 1948-07-20 Elevator Supplies Co Inc Electric treadle
US2471601A (en) * 1944-04-28 1949-05-31 Philco Corp Variable resistance phonograph pickup
US2472214A (en) * 1947-10-22 1949-06-07 Hurvitz Hyman Pressure responsive electrical resistor
US2545737A (en) * 1947-11-01 1951-03-20 Goodrich Co B F Variable resistance pickup element
US2548947A (en) * 1946-03-12 1951-04-17 Socony Vacuum Oil Co Inc Pressure measuring device
US2624822A (en) * 1950-07-29 1953-01-06 Gen Electric Rheostat
US2626381A (en) * 1948-01-27 1953-01-20 Texas Instruments Inc Variable resistance distributed seismometer
US2649579A (en) * 1950-02-01 1953-08-18 Standard Oil Dev Co Detector for seismic exploration
US2688070A (en) * 1950-03-14 1954-08-31 Dayton Rubber Company Electrically heated mattress construction
US2690489A (en) * 1949-01-08 1954-09-28 Jarret Jean Marie Baptiste Conductor device having a variable electric resistance
US2759552A (en) * 1951-10-01 1956-08-21 Exxon Research Engineering Co Seismic exploration apparatus
US3125739A (en) * 1964-03-17 Electric controller
US3386067A (en) * 1967-04-24 1968-05-28 Raphael J. Costanzo Pressure-sensitive electrical switch and application therefor
US3451032A (en) * 1966-07-15 1969-06-17 Omsteel Ind Inc Electromechanical transducer material
US3509296A (en) * 1967-10-23 1970-04-28 Ncr Co Resilient variable-conductivity circuit controlling means
US3676815A (en) * 1969-07-28 1972-07-11 Essex International Inc Thermally sensitive controls for electric circuits
US3794790A (en) * 1972-02-04 1974-02-26 Rists Wires & Cables Ltd Electrical switches
US4072832A (en) * 1974-09-03 1978-02-07 Siemens Aktiengesellschaft Control electrode for high-voltage apparatus
US4143367A (en) * 1976-10-02 1979-03-06 Erwin Sick Gessellschaft Mit Beschrankter Haftung Optik-Electronik Safety device for limiting the movement of doors and the like on contact with an obstacle
US4503416A (en) * 1982-12-13 1985-03-05 General Electric Company Graphite fiber tactile sensor
US4639710A (en) * 1986-01-24 1987-01-27 Mcmillan Thomas A Foot pedal for varying resistance in an electrical circuit
EP0277362A2 (en) * 1987-02-05 1988-08-10 LEDA Logarithmic Electrical Devices for Automation S.r.l. Process for producing electric resistors having a wide range of specific resistance values
US5116051A (en) * 1989-01-12 1992-05-26 Atari Games Corporation Strain gauge pressure-sensitive video game control

Cited By (24)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3125739A (en) * 1964-03-17 Electric controller
US2471601A (en) * 1944-04-28 1949-05-31 Philco Corp Variable resistance phonograph pickup
US2445660A (en) * 1945-08-17 1948-07-20 Elevator Supplies Co Inc Electric treadle
US2548947A (en) * 1946-03-12 1951-04-17 Socony Vacuum Oil Co Inc Pressure measuring device
US2472214A (en) * 1947-10-22 1949-06-07 Hurvitz Hyman Pressure responsive electrical resistor
US2545737A (en) * 1947-11-01 1951-03-20 Goodrich Co B F Variable resistance pickup element
US2626381A (en) * 1948-01-27 1953-01-20 Texas Instruments Inc Variable resistance distributed seismometer
US2690489A (en) * 1949-01-08 1954-09-28 Jarret Jean Marie Baptiste Conductor device having a variable electric resistance
US2649579A (en) * 1950-02-01 1953-08-18 Standard Oil Dev Co Detector for seismic exploration
US2688070A (en) * 1950-03-14 1954-08-31 Dayton Rubber Company Electrically heated mattress construction
US2624822A (en) * 1950-07-29 1953-01-06 Gen Electric Rheostat
US2759552A (en) * 1951-10-01 1956-08-21 Exxon Research Engineering Co Seismic exploration apparatus
US3451032A (en) * 1966-07-15 1969-06-17 Omsteel Ind Inc Electromechanical transducer material
US3386067A (en) * 1967-04-24 1968-05-28 Raphael J. Costanzo Pressure-sensitive electrical switch and application therefor
US3509296A (en) * 1967-10-23 1970-04-28 Ncr Co Resilient variable-conductivity circuit controlling means
US3676815A (en) * 1969-07-28 1972-07-11 Essex International Inc Thermally sensitive controls for electric circuits
US3794790A (en) * 1972-02-04 1974-02-26 Rists Wires & Cables Ltd Electrical switches
US4072832A (en) * 1974-09-03 1978-02-07 Siemens Aktiengesellschaft Control electrode for high-voltage apparatus
US4143367A (en) * 1976-10-02 1979-03-06 Erwin Sick Gessellschaft Mit Beschrankter Haftung Optik-Electronik Safety device for limiting the movement of doors and the like on contact with an obstacle
US4503416A (en) * 1982-12-13 1985-03-05 General Electric Company Graphite fiber tactile sensor
US4639710A (en) * 1986-01-24 1987-01-27 Mcmillan Thomas A Foot pedal for varying resistance in an electrical circuit
EP0277362A2 (en) * 1987-02-05 1988-08-10 LEDA Logarithmic Electrical Devices for Automation S.r.l. Process for producing electric resistors having a wide range of specific resistance values
EP0277362A3 (en) * 1987-02-05 1989-09-20 Leda Logarithmic Electrical Devices For Automation S.R.L. Process for producing electric resistors having a wide range of specific resistance values
US5116051A (en) * 1989-01-12 1992-05-26 Atari Games Corporation Strain gauge pressure-sensitive video game control

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