Patent Number: 047479981
Section: claims

1. A thermally actuated thermionic switch which responds electrically to an increase in temperature of thermionic material therein by changing from a high impedance to a low impedance at a predetermined temperature set point, comprising: an emitter constituting an outer casing of said switch and adapted to be in contact with an associated medium which may undergo a change in temperature, said outer casing having a closed end and an open end,  a collector positioned totally within said emitter and separated therefrom by a gap, said collector including a hollow longitudinally extending annular section and a hollow reduced diameter section, said collector being electrically isolated from said emitter and retained within said emitter by an insulator member positioned within said emitter, said insulator member being located intermediate said reduced diameter section of said collector and an inner surface of said emitter,  means for closing said open end of said outer casing formed by said emitter for defining a closed volume within said emitter,  electrical lead means connected to said inner surface of said emitter and to said reduced diameter section of said collector and extending through said means for closing said outer casing for connection to an associated power supply and to an associated point of use, and  a quantity of thermionic material held in a matrix in a graphite block reservoir, and which is located within said emitter, said thermionic material consisting of metal which ionizes when heated to a temperature above said set point, for electrically connecting said emitter and collector when said thermionic material is ionized,  whereby upon said thermionic material ionizing, said switch changes from high impedance to low impedance allowing the conduction of large electrical currents therethrough.  said thermionic switch containing a quantity of thermionic material which ionizes when heated to a predetermined temperature above said set point, said thermionic material constituting a metal held in a matrix in a graphite block reservoir, said switch additionally including:  an emitter electrode defining an outer body of said switch and adapted to be in contact with an associated coolant, said outer body having a closed end and an open end, said graphite block reservoir being secured to an inner surface of said emitter electrode.  a collector electrode located totally within and spaced from said emitter electrode, said collector electrode including a hollow longitudinally extending annular section and a hollow reduced diameter end section,  an insulator member secured to an inner surface of said emitter electrode and secured to an outer surface of said collector electrode for retaining said collector electrode within said emitter electrode and for electrically isolating same,  means containing insulative material for closing said open end of said emitter electrode for forming a closed volume therein, and  electrical lead means connected to said inner surface of said emitter electrode and to said collector electrode and extending through said closing means and adapted to be connected to an associated electrical circuit for controlling same,  said quantity of thermionic material being located within said emitter electrode for electrically connecting said emitter electrode and collector electrode when said material is ionized so as to change said switch from high impedance to low impedance allowing the conduction of electrical current therethrough.  an emitter electrode constructed to define an outer casing having an open end and a closed end and constructed to form a space therein,  means comprising an insulator member for closing said open end of said emitter electrode for defining a closed volume,  a collector electrode located totally within said space and spaced from said emitter electrode so as to form a gap therebetween, said collector electrode including a hollow longitudinally extending annular section and a hollow reduced diameter section,  insulator means positioned totally within said space formed by said emitter electrode for retaining said collector electrode within said emitter electrode and for electrically isolating said collector electrode from said emitter electrode, said insulator means being positioned intermediate an outer surface of said collector electrode and an inner surface of said emitter electrode,  electric lead means connected to said inner surface of said emitter electrode and to said reduced diameter section of said collector electrode, extending through said closing means, and adapted to be connected to an associated power supply and to an associated point of use, and  a quantity of thermionic material selected from the group consisting of cesium, sodium, potassium and rubidium, which ionizes upon being heated to a predetermined temperature, located within said emitter electrode and held in a matrix in a graphite block reservoir so as to be adjacent said emitter electrode for electrically connecting said emitter electrode and said collector electrode when said material ionizes, such that large electrical currents are allowed to pass through said switch from an associated power supply to an associated point of use due to said switch changing from a high impedance to a low impedance at a predetermined temperature. 2. The thermionic switch of claim 1, wherein said thermionic material is a metal which is liquid at a desired operation temperature. 3. The thermionic switch of claim 1, wherein said metal is selected from the group consisting of cesium, sodium potassium and rubidium. 4. The thermionic switch of claim 1, wherein said set point is in a range of about 565.degree.-570.degree. C., and wherein said thermionic material consists of a cesium loaded graphite block secured to an inner surface of said emitter. 5. The thermionic switch of claim 1, wherein said means for closing said outer casing comprises a member containing insulative material secured in and extending into said emitter, through which said electrical lead means extend. 6. A thermionic switch which responds electrically upon an increase in temperature, which ionizes thermionic material therein, by changing from a high impedance to a low impedance at a predetermined temperature set point and adapted to be responsive to coolant temperature: 7. The improvement of claim 6, wherein said temperature set point is in the range of about 565.degree.-570.degree. C., and wherein said quantity of thermionic material consists of a cesium loaded graphite block. 8. The improvement of claim 6, wherein said metal is cesium, and wherein said temperature set point is in a range of about 565.degree.-570.degree. C. 9. A thermally actuated thermionic switch which changes from a high impedance to a low impedance upon ionization of thermionic material therein at a predetermined temperature such that large electrical currents are allowed to flow therethrough, comprising: 10. The thermionic switch of claim 9, wherein said emitter electrode is constructed to include a longitudinally extending annular section, a closed end section and an open end section, said collector electrode and said insulator means being located within said longitudinally extending annular section of said emitter electrode, said thermionic material being located in said closed end section of said emitter electrode and said insulator member through which said electrical lead means extend being located in said open end section of said emitter electrode. 11. The thermionic switch of claim 6, wherein said quantity of thermionic material is selected from the group consisting of cesium, sodium, potassium and rubidium.