US2031966A - Centrifugal thermoelectric machine - Google Patents
Centrifugal thermoelectric machine Download PDFInfo
- Publication number
- US2031966A US2031966A US754925A US75492534A US2031966A US 2031966 A US2031966 A US 2031966A US 754925 A US754925 A US 754925A US 75492534 A US75492534 A US 75492534A US 2031966 A US2031966 A US 2031966A
- Authority
- US
- United States
- Prior art keywords
- thermo
- junctions
- couple
- casing
- rotor
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Lifetime
Links
Images
Classifications
-
- H—ELECTRICITY
- H10—SEMICONDUCTOR DEVICES; ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
- H10N—ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
- H10N10/00—Thermoelectric devices comprising a junction of dissimilar materials, i.e. devices exhibiting Seebeck or Peltier effects
Definitions
- thermo-couple generators of electricity relate to thermo-couple generators of electricity and more specifically relates to a generator in which useful temperature con ditions are maintained in a fluid which surrounds or envelops the thermo-couple junctions, by centrifuging the fluid.
- thermo-electric action within thermocouples physicists have long been acquainted with the fact that when certain pairs of different metals or alloys are joined together, as by twisting or joining together the ends of two difierent metal wires, then if the two opposite junctions are maintained at different temperatures, electromotive force is created within the junctions and metals. current to flow in the circuit of the metals. The direction of the current fiow depends on the metallic elements selected, as well as the temperatures created in opposite junctions. The reverse action is also known-that an electric current supplied to the thermo-couple circuit, tends to create temperature differences at the thermocouple junctions.
- thermo-couples may be made from copper wire and iron wire; or constantan wire and iron wire, by twisting, welding, or otherwise making electrical connection of the ends. In doing this, the junction must consist of two different metal wire ends. Bismuth, platinum, lead, silver and antimony are some other metals frequently joined together in the making of thermo-couples.
- thermo-couple circuits are quite small, being commonly measured electrically in microvolts per degree of temperature difference, or, fractions of calories thermally.
- thermo-couple circuits are often made with thermo-couples connected in series.
- thermo-oouples
- my invention comprises a radial arrangement of thermo-couples, with opposite junctions placed towards the outer and inner 5 diameter of the structure respectively. These junctions utilize the different temperature conditions maintained thereby centrifuging a fiuid contained within the structure and in thermal contact with the thermo-couple junctions.
- thermo-couple generator of electricity It is an object of my invention to provide a thermo-couple generator of electricity. A further object is to provide such a generator in which temperature differences at the junctions of the thermo-couples is maintained by centrifuging a 15 fluid in contact with the thermo-couples. Another object is to provide such a generator in which the junctions of the thermo-couples are arranged annularly. Further objects will appear hereinafter.
- Figure 1 is a longitudinal elevational view of the machine, with certain parts shown in section,
- Figure 2 is a transverse vertical section, taken 25 along the line 2-2 of Figure 1,
- FIG. 3 illustrates various forms of junctions
- Figure 4 is an enlarged cross-section of the rotor shaft, with radial conduits indicated in positions, 30
- Figure 5 is a vertical section of an alternative form of rotor unit, the lower quadrant being rotated 45 to throw it into section, and
- Figure 6 is a fragmentary section of the alternative form of rotor unit taken through the cen- 35 ter of Figure 5.
- a base I and pedestals 2 and 3 form the support of the machine.
- the pedestals 2 and 3 are fitted with bearings 4 in which the shaft 5 is free to revolve.
- a pulley 6 is keyed to the shaft 5.
- the shaft 5 is drilled longitudinally to provide conduits I and 8, and is drilled radially to provide ports 9 and II], which are degrees apart.
- Supply pipes II and I2 are screwed into the conduits 1 and 8 of the shaft respectively. These supply pipes are journaled so as to permit supply of a fiuid through the shaft when the shaft is in revolution.
- tor units I3, I4, I5, I6, I'I, I8 and I9 is the same, in that they are cast or molded from a suitable insulating material, such as bakelite, glass, cellulose acetate or the like-and which can be cast with suitable inserts as hereinafter described.
- a suitable insulating material such as bakelite, glass, cellulose acetate or the like-and which can be cast with suitable inserts as hereinafter described.
- each rotor unit Cast also in each rotor unit is a structure of thermo-couples illustrated diagrammatically in Figure 2 as 22 and 23; and also indicated conventionally in Figure 1 in rotor I6. While innumerable pairs of metals may be chosen as previously mentioned; in this machine one metallic element is represented as 22 (such as iron) the other metallic element as 23 (such as copper). The metallic elements alternate in the arrangement and by their connections, form an assembly of thermo-couples connected in series. In the diagram of Figure 2 one end of the series is shown in contact with a slip ring 24.
- thermo-couples which are in contact with each other at various points in the winding, the individual thermo-couples are coated with electric insulating enamel or varnish, so that the entire thermo-couple structure becomes electrically insulated.
- thermo-couples in each rotor is exceedingly large, and may be still further increased by increasing the width of the rotor unit.
- thermo-couple structure in one of the rotor units is essentially one of thousands of thermo-couples of small Wire, or of thin stampings of the sheet metals, or of other adaptable shapes and cross-sections; Junctions may be formed by welding, soldering, mechanical fastening, or otherwise connecting the ends of the two different metals to each other.
- thermo-couple structure as above described will be readily apparent.
- slip-rings 24 and 25 may be of copper, and a pair of rings encircle each rotor. It is to these slip-rings that electrical end connections of the thermo-couple assembly are madeand through which rings, along with contact fingers 26 and 21, and terminals 28, that electric current may be supplied or taken off from the machine.
- Contact fingers 26 and 27 are mounted on fiber insulating blocks 29, fastened to the base I. Contact fingers are shown in Figure 1, only on rotor units I5 and I6, although they are intended to be used with all rotor units and are indicated for simplicity by arrows properly positioned at the slip-rings.
- FIG. 3 illustrates how thermo-couple junctions may be made by twisting, welding or brazing the wire ends.
- thermocouples A Variation in arrangement of the thermocouples is illustrated in the modified rotor unit of Figures 5 and 6 in which the radial arrangement of individual thermo-couples is not followed; nevertheless opposite junctions are still located towards inner and outer diameters respectively.
- the ends of the thermo-couple assembly are also fastened to slip-rings on the rotor unit.
- Figure 6 Only one quadrant of the four designed for each rotor unit, and while such a construction can function satisfactorily in the machine of this application, a further and more eificient use is indicated in my application Serial No. 754,926, of even date.
- the rotor units I3, I4, I5, I6, I'I, I8 and I9 contain an electrically non-conductive fluid which completely fills the annular chambers therein, and which completely surrounds the countless thermo-couples and thermo-couple junctions.
- I may use any suitable electrically non-conducting fluid, such as transformer oil, glycerin, and the like or even a conducting fluid, if the thermocouple wires are well insulated. If the rotor be revolved through application of suitable power at pulley 6, the molecules of the fluid will all be acted upon by centrifugal force.
- thermocouple junctions are also placed at these inner and outer peripheries and acquire temperatures of the fluid at those positions, through conduction of heat, electric current is produced in the thermo-couple structure and taken off at sliprings 24 and 25.
- thermo-couple structure If the cycle just previously described be reversed, and electric energy be supplied the thermo-couple structure from an external source, then heating and cooling effects will be created at opposite thermo-couple junctions; and through the heat exchange and centrifugal action in the fluid, cold fluid may be made to pass through passage-ways 3
- thermo-couple units spaced an equal number of degrees apart about the axis of the rotor and contained in the rotor casing
- thermo-electric machine comprising a rotatable casing containing an electrically nonconductive liquid and mounted upon an axis, a thermo-couple system contained therein and enveloped by said liquid, onetset of junctions of which system are located near the periphery of said casing and the other set of junctions of which system are located in proximity to the center of said casing, and means for removing electricity from said system when the casing is rotated upon its axis.
- thermo-electric machine comprising 2. cylindrical rotatable casing containing an electrically non-conductive liquid and mounted upon an axis, a thermo-couple system contained therein and enveloped by said liquid, one set of junctions of which system are located substantially annularly near the periphery of said casing and the other set of junctions of which system are located substantially annularly near the center of said casing, and means connected with said thermo-couple system for removing electricity therefrom when the casing is rotated upon its axis.
- thermo-electric machine comprising a cylindrical rotatable casing containing an electrically non-conductive liquid and mounted upon an axis, a thermo-couple system contained therein and enveloped by said liquid, the elements of which system are substantially radially positioned with respect to the axis of the casing and one set of junctions of which system are substantially annularly located near the periphery of the casing and the other set of junctions of which system are substantially annularly located near the center of the casing, and means for removing electricity from said system when the casing is rotated upon its axis.
- thermo-electric machine comprising a, cylindrical rotatable casing containing an electrically non-conductive liquid and mounted upon an axis, four quadrants of thermo-couples contained therein and located 90 apart, and enveloped by said liquid, one set of junctions of each quadrant being located near the periphery of said casing and the other set of junctions of each quadrant being located in proximity to the center of said casing, and means connected with the four quadrants for removing electricity therefrom when the casing is rotated upon its axis.
- thermo-electric machine comprising a shaft and means for rotating the shaft, a casing containing an electrically non-conductive liquid mounted upon said shaft and adapted to rotate therewith, a thermo-couple system contained in the casing having one set of junctions near the periphery and the other set near the center of said casing, and which are enveloped by said liquid, openings in the shaft and the casing for introducing hot electrically nonconductive liquid thereto and openings in the shaft and casing for removing cold liquid therefrom, and means for removing electricity from said system when the casing is rotated upon its axis.
Landscapes
- Centrifugal Separators (AREA)
Description
Feb. 25, 1936. R MATH A T 2,031,966
GENTRIFUGAL THERMOELECTRIC MACHINE 'Filed NOV. 26, 1934 Patented Feb. 25, 1936 UNITED STATES PATENT OFFICE CENTRIFUGAL THERMOELECTRIC MACHINE 5 Claims.
This invention relates to thermo-couple generators of electricity and more specifically relates to a generator in which useful temperature con ditions are maintained in a fluid which surrounds or envelops the thermo-couple junctions, by centrifuging the fluid.
Most fluids contain molecules of different temperatures; these molecules may be made to take certain annular positions about an axis by centrifuging the fluid-the heavier and usually cooler molecules being forced towards the outer periphery, and the lighter and usually warmer molecules taking a position towards the inner periphery. It is the function of this machine to take advantage of this action through the placement of thermo-couple junctions in such annular positions, as to utilize the various temperature conditions maintained there.
As to the thermo-electric action within thermocouples, physicists have long been acquainted with the fact that when certain pairs of different metals or alloys are joined together, as by twisting or joining together the ends of two difierent metal wires, then if the two opposite junctions are maintained at different temperatures, electromotive force is created within the junctions and metals. current to flow in the circuit of the metals. The direction of the current fiow depends on the metallic elements selected, as well as the temperatures created in opposite junctions. The reverse action is also known-that an electric current supplied to the thermo-couple circuit, tends to create temperature differences at the thermocouple junctions.
Suitable thermo-couples may be made from copper wire and iron wire; or constantan wire and iron wire, by twisting, welding, or otherwise making electrical connection of the ends. In doing this, the junction must consist of two different metal wire ends. Bismuth, platinum, lead, silver and antimony are some other metals frequently joined together in the making of thermo-couples.
The electric energy, or heating and cooling effects, that may be created in any thermo-couple circuit with but two junctions is quite small, being commonly measured electrically in microvolts per degree of temperature difference, or, fractions of calories thermally. To increase the amount of energy, thermo-couple circuits are often made with thermo-couples connected in series.
Considerable. information on the actions and effects within thermo-oouples is available. in
Generally this causes an electric countless texts on physics and electricity, and further elaboration is hardly necessary here.
More specifically, my invention comprises a radial arrangement of thermo-couples, with opposite junctions placed towards the outer and inner 5 diameter of the structure respectively. These junctions utilize the different temperature conditions maintained thereby centrifuging a fiuid contained within the structure and in thermal contact with the thermo-couple junctions.
It is an object of my invention to provide a thermo-couple generator of electricity. A further object is to provide such a generator in which temperature differences at the junctions of the thermo-couples is maintained by centrifuging a 15 fluid in contact with the thermo-couples. Another object is to provide such a generator in which the junctions of the thermo-couples are arranged annularly. Further objects will appear hereinafter.
In the accompanying drawing, in which like reference numerals refer to like parts:
Figure 1 is a longitudinal elevational view of the machine, with certain parts shown in section,
Figure 2 is a transverse vertical section, taken 25 along the line 2-2 of Figure 1,
Figure 3 illustrates various forms of junctions,
Figure 4 is an enlarged cross-section of the rotor shaft, with radial conduits indicated in positions, 30
Figure 5 is a vertical section of an alternative form of rotor unit, the lower quadrant being rotated 45 to throw it into section, and
Figure 6 is a fragmentary section of the alternative form of rotor unit taken through the cen- 35 ter of Figure 5.
A base I and pedestals 2 and 3 form the support of the machine. The pedestals 2 and 3 are fitted with bearings 4 in which the shaft 5 is free to revolve. A pulley 6 is keyed to the shaft 5.
The shaft 5 is drilled longitudinally to provide conduits I and 8, and is drilled radially to provide ports 9 and II], which are degrees apart.
Supply pipes II and I2 are screwed into the conduits 1 and 8 of the shaft respectively. These supply pipes are journaled so as to permit supply of a fiuid through the shaft when the shaft is in revolution.
Mounted and keyed to the shaft 5, are seven cylindrical units l3, I4, l5, l6, l1, l8 and. I9. These units and the shaft on which they are mounted, form the rotor of the structure. Thrust or spacer washers 20, are provided to minimize end-play. The general construction of these ro- ,55
tor units I3, I4, I5, I6, I'I, I8 and I9 is the same, in that they are cast or molded from a suitable insulating material, such as bakelite, glass, cellulose acetate or the like-and which can be cast with suitable inserts as hereinafter described. The molding of countless electrically non-conducting, or insulating materials in diverse shapes, sizes and inserts is well known to those skilled in the molding art, and further description of these operations is not necessary in this application.
Cast also in each rotor unit is a structure of thermo-couples illustrated diagrammatically in Figure 2 as 22 and 23; and also indicated conventionally in Figure 1 in rotor I6. While innumerable pairs of metals may be chosen as previously mentioned; in this machine one metallic element is represented as 22 (such as iron) the other metallic element as 23 (such as copper). The metallic elements alternate in the arrangement and by their connections, form an assembly of thermo-couples connected in series. In the diagram of Figure 2 one end of the series is shown in contact with a slip ring 24. The other end carries an arrow indicating a continuation of the progression, around and around in the rotor, until the series fills the chamber 2 I; whereupon the remaining end is connected to a second slip ring 25, indicated in rotor I6 of Figure I. To avoid short-circuiting of thermo-couples which are in contact with each other at various points in the winding, the individual thermo-couples are coated with electric insulating enamel or varnish, so that the entire thermo-couple structure becomes electrically insulated.
The number of thermo-couples in each rotor is exceedingly large, and may be still further increased by increasing the width of the rotor unit.
The construction of the thermo-couple structure in one of the rotor units is essentially one of thousands of thermo-couples of small Wire, or of thin stampings of the sheet metals, or of other adaptable shapes and cross-sections; Junctions may be formed by welding, soldering, mechanical fastening, or otherwise connecting the ends of the two different metals to each other. To one skilled in the art in the formation of wire coils, webs, networks, and other windings, together with the maintenance of suitable electric insulation between the elements of the unit, the construction of such a thermo-couple structure as above described will be readily apparent.
A reason for the size and plurality of rotor units in this drawing is in the adaptability of such a construction for use in the inventions of my application Serial Number 754,926, for Thermoelectric motor-generator and my application Serial Number 754,927, for Thermo-electric turbine, all of even date, to which reference is made.
Referring again to slip- rings 24 and 25, these may be of copper, and a pair of rings encircle each rotor. It is to these slip-rings that electrical end connections of the thermo-couple assembly are madeand through which rings, along with contact fingers 26 and 21, and terminals 28, that electric current may be supplied or taken off from the machine.
Contact fingers 26 and 27, are mounted on fiber insulating blocks 29, fastened to the base I. Contact fingers are shown in Figure 1, only on rotor units I5 and I6, although they are intended to be used with all rotor units and are indicated for simplicity by arrows properly positioned at the slip-rings.
Figure 3 illustrates how thermo-couple junctions may be made by twisting, welding or brazing the wire ends.
A Variation in arrangement of the thermocouples is illustrated in the modified rotor unit of Figures 5 and 6 in which the radial arrangement of individual thermo-couples is not followed; nevertheless opposite junctions are still located towards inner and outer diameters respectively. The ends of the thermo-couple assembly are also fastened to slip-rings on the rotor unit. There is illustrated in Figure 6, only one quadrant of the four designed for each rotor unit, and while such a construction can function satisfactorily in the machine of this application, a further and more eificient use is indicated in my application Serial No. 754,926, of even date.
Referring now to the operation of the machine. The rotor units I3, I4, I5, I6, I'I, I8 and I9 contain an electrically non-conductive fluid which completely fills the annular chambers therein, and which completely surrounds the countless thermo-couples and thermo-couple junctions. I may use any suitable electrically non-conducting fluid, such as transformer oil, glycerin, and the like or even a conducting fluid, if the thermocouple wires are well insulated. If the rotor be revolved through application of suitable power at pulley 6, the molecules of the fluid will all be acted upon by centrifugal force. If a portion of the fluid be withdrawn now through the passageway 3I, and in its place hot fluid be supplied, through passage-ways I and 30, then the hot molecules will take an annular position towards the inner periphery of the chambers, while the cooler molecules will remain at the outer periphery of the chamber. Since opposite thermocouple junctions are also placed at these inner and outer peripheries and acquire temperatures of the fluid at those positions, through conduction of heat, electric current is produced in the thermo-couple structure and taken off at sliprings 24 and 25.
As hot molecules lose some of their heat, becoming cooler and denser, they are forced by centrifugal force towards the outer periphery, and the hotter molecules supplied in the fluid take the inner annular position.
One exception to the production of electric current in this machine exists in that instance wherein temperatures of opposite junctions have become equally higher and lower than the neutral-point of the pair of metals used in the thermo-couples. No net electric current will be available under circumstances as these. The theory of this subject, as well as that of direction of current flow, is treated in innumerable physics texts.
If the cycle just previously described be reversed, and electric energy be supplied the thermo-couple structure from an external source, then heating and cooling effects will be created at opposite thermo-couple junctions; and through the heat exchange and centrifugal action in the fluid, cold fluid may be made to pass through passage-ways 3| and 8; or hot fluid passed through passage-ways 30 and 1.
While in Figs. 5 and 6 I have shown four quadrants or units, it will be understood that I may employ six, eight, ten, twelve or even more thermo-couple units spaced an equal number of degrees apart about the axis of the rotor and contained in the rotor casing,
What I claim as my invention and desire to be secured by Letters Patent of the United States is:
1. A thermo-electric machine comprising a rotatable casing containing an electrically nonconductive liquid and mounted upon an axis, a thermo-couple system contained therein and enveloped by said liquid, onetset of junctions of which system are located near the periphery of said casing and the other set of junctions of which system are located in proximity to the center of said casing, and means for removing electricity from said system when the casing is rotated upon its axis.
2. A thermo-electric machine comprising 2. cylindrical rotatable casing containing an electrically non-conductive liquid and mounted upon an axis, a thermo-couple system contained therein and enveloped by said liquid, one set of junctions of which system are located substantially annularly near the periphery of said casing and the other set of junctions of which system are located substantially annularly near the center of said casing, and means connected with said thermo-couple system for removing electricity therefrom when the casing is rotated upon its axis.
3. A thermo-electric machine comprising a cylindrical rotatable casing containing an electrically non-conductive liquid and mounted upon an axis, a thermo-couple system contained therein and enveloped by said liquid, the elements of which system are substantially radially positioned with respect to the axis of the casing and one set of junctions of which system are substantially annularly located near the periphery of the casing and the other set of junctions of which system are substantially annularly located near the center of the casing, and means for removing electricity from said system when the casing is rotated upon its axis.
4. A thermo-electric machine comprising a, cylindrical rotatable casing containing an electrically non-conductive liquid and mounted upon an axis, four quadrants of thermo-couples contained therein and located 90 apart, and enveloped by said liquid, one set of junctions of each quadrant being located near the periphery of said casing and the other set of junctions of each quadrant being located in proximity to the center of said casing, and means connected with the four quadrants for removing electricity therefrom when the casing is rotated upon its axis.
5. A thermo-electric machine comprising a shaft and means for rotating the shaft, a casing containing an electrically non-conductive liquid mounted upon said shaft and adapted to rotate therewith, a thermo-couple system contained in the casing having one set of junctions near the periphery and the other set near the center of said casing, and which are enveloped by said liquid, openings in the shaft and the casing for introducing hot electrically nonconductive liquid thereto and openings in the shaft and casing for removing cold liquid therefrom, and means for removing electricity from said system when the casing is rotated upon its axis.
ROBERT J. m'rnms.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US754925A US2031966A (en) | 1934-11-26 | 1934-11-26 | Centrifugal thermoelectric machine |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US754925A US2031966A (en) | 1934-11-26 | 1934-11-26 | Centrifugal thermoelectric machine |
Publications (1)
Publication Number | Publication Date |
---|---|
US2031966A true US2031966A (en) | 1936-02-25 |
Family
ID=25036968
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US754925A Expired - Lifetime US2031966A (en) | 1934-11-26 | 1934-11-26 | Centrifugal thermoelectric machine |
Country Status (1)
Country | Link |
---|---|
US (1) | US2031966A (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2516719A (en) * | 1947-06-05 | 1950-07-25 | Herschel G Pack | Thermoelectric generator |
US3064063A (en) * | 1959-11-05 | 1962-11-13 | Thermo Power Inc | Thermoelectric generator |
-
1934
- 1934-11-26 US US754925A patent/US2031966A/en not_active Expired - Lifetime
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2516719A (en) * | 1947-06-05 | 1950-07-25 | Herschel G Pack | Thermoelectric generator |
US3064063A (en) * | 1959-11-05 | 1962-11-13 | Thermo Power Inc | Thermoelectric generator |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
US2734344A (en) | lindenblad | |
US3794527A (en) | Thermoelectric converter | |
US3269872A (en) | Thermoelectric device and method of manufacture | |
US2031966A (en) | Centrifugal thermoelectric machine | |
US2390578A (en) | Thermoelectric generator | |
GB1123312A (en) | Brushless synchronous a.c. generator | |
US4047063A (en) | Liquid metal slip-ring arrangement for a dynamo electric machine | |
US2597752A (en) | Thermoelectric power generator | |
US3064063A (en) | Thermoelectric generator | |
US4227102A (en) | Electrical machine with cryogenic cooling | |
US3155856A (en) | Dynamoelectric machinery | |
US3183121A (en) | Thermoelectric generator with heat transfer and thermal expansion adaptor | |
US2380346A (en) | Apparatus for heating air or other fluid | |
US3238396A (en) | Heat motor with a dielectric rotor | |
US3211586A (en) | Thermoelectric converter | |
US3757146A (en) | Thermoelectric generator | |
ATE55518T1 (en) | STATOR WITH SUPERCONDUCTING THREE-PHASE WINDINGS. | |
US2181921A (en) | Induction furnace | |
US1193467A (en) | Apparatus for cooling heated air by electric currents | |
US2857446A (en) | Method and apparatus for converting heat directly to electricity | |
US1944952A (en) | Homopolar generator | |
US3514653A (en) | Antifriction slipring device | |
US2703868A (en) | Multiple slip ring joint | |
US2263719A (en) | Liquid circulator | |
JPH0197147A (en) | Heat generating motor |