Thermoelectric generators are devices that produce heat (e.g., via combustion or radioactive decay) and convert the heat directly into electrical energy. Thermoelectric generators are more simple and reliable than conventional generators that use rotating components because they typically have fewer moving parts and require less maintenance.
Due to their exceptional reliability, thermoelectric generators are particularly well suited for remote installations and applications where maintenance is prohibitive. For example, thermoelectric generators fueled by radioisotopes are commonly employed as power sources for satellites and spacecraft where the vehicles are inaccessible after launch.
Unfortunately, there are deficiencies in conventional thermoelectric generators. Many thermoelectric generators use radioisotope fuels as a source of heat. However, the radioisotope fuels in such generators immediately start to decay once the generators are assembled. Thus, conventional thermoelectric generators constructed with radioisotope fuels generally cannot be stored for extended periods of time before they are used. In addition, conventional thermoelectric generators fueled by radioisotopes require high purity radioisotopes such as plutonium. Production of high purity plutonium is prohibitively expensive. Additionally, handling and storage of plutonium requires extreme caution and costly safeguards. Further, spent plutonium waste is radioactive and, as a result, handling, disposal and storage of spent material is problematic and costly due to the prolonged half-life of plutonium isotopes.
In contrast with conventional approaches, improved techniques are directed to thermoelectric generators which employ a safe, initially dormant, stable, non-radioactive fuel sample which is activated on-demand by a neutron source which initiates and controls activation of the fuel sample. The improved techniques thus allow thermoelectric generators to be fully assembled and stored for extended periods of time before they are deployed for use, and then activated on demand only when the need arises for them to generate power.
In some examples, the fuel source includes radioactively stable Bismuth 209 (Bi209), which converts to Bi210 when it is exposed to neutron radiation. The Bi210 then radioactively decays into Polonium 210 (Po210), which in turn radioactively decays into stable lead (Pb206). Thus, not only is the fuel sample initially stable, but also it is stable after the fuel is spent. Moreover, radioactive decay of Po210 merely releases alpha particles, which are generally harmless to humans unless ingested or inhaled.
Some embodiments are directed to a thermoelectric generator with on-demand activation. The thermoelectric generator includes a fuel sample and a neutron source constructed and arranged to emit neutrons into the fuel sample to initiate radioactive decay reactions in the fuel sample in response to the neutron source receiving an activation input. The thermoelectric generator also includes a thermoelectric converter coupled to the fuel sample to convert thermal energy from the radioactive decay reactions to electrical energy
Other embodiments are directed to a method for generating electrical power on demand. The method includes receiving an activation input and, in response to receiving the activation input, activating a neutron source to irradiate a fuel sample with neutrons to initiate radioactive decay reactions in the fuel sample to generate heat. The method further includes converting the heat from the radioactive decay reactions to electrical energy.
Further embodiments are directed to a thermoelectric generator with on-demand activation which includes multiple fuel samples each including Bi209. The thermoelectric generator further includes multiple neutron sources, each neutron source disposed in relation to one of the fuel samples to emit neutrons into the respective fuel sample to initiate radioactive decay reactions in the fuel sample in response to the neutron source receiving an activation input. The thermoelectric generator further includes multiple thermoelectric converters, each thermoelectric converter coupled a respective one of the fuel samples to convert thermal energy from the radioactive decay reactions in the fuel sample to electrical energy. The thermoelectric generator further includes control circuitry coupled to each of the neutron sources to provide the respective activation input to each of the neutron sources, wherein the control circuitry is constructed and arranged to apply activation inputs to the neutron sources in a timing sequence to expose the respective fuel samples to neutron emission at different times, such that, as radioactive decay reactions in one fuel sample diminish over time, radioactive decay reactions in another fuel sample are increased to extend a service life of the thermoelectric generator.
The foregoing and other features and advantages will be apparent from the following description of particular embodiments of the invention, as illustrated in the accompanying drawings, in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating the principles of various embodiments of the invention. In the accompanying drawings,
Embodiments of the invention will now be described. It is understood that such embodiments are provided by way of example to illustrate various features and principles of the invention, and that the invention hereof is broader than the specific example embodiments disclosed.
Improved techniques are directed to thermoelectric generators which employ a safe, initially dormant, stable, non-radioactive fuel sample which is activated on-demand by a neutron source which initiates and controls activation of the fuel sample. An activation input activates the neutron source to emit neutrons into the fuel sample and cause radioactive decay reactions that generate heat. A thermoelectric converter coupled to the fuel sample converts thermal energy produced by the radioactive decay reactions to electrical energy.
In an example, a stable non-radioactive fuel sample includes Bi209. Upon exposure to neutron irradiation, the Bi209 undergoes conversion to Po210 which undergoes radioactive decay to stable Pb206 and generates heat. Heat energy is generated primarily from radioactive decay of Po210.
In some examples, control circuitry 150 provides the activation input 152. The control circuitry 150 may be coupled to a communication receiver 170 to receive communication signals, such as a remote activation signal, and to a timing circuit 180 (e.g., a clock) to provide the control circuitry 150 with a timing reference.
In some examples, the thermoelectric converters 130 are coupled to a power management module 140 that produces regulated electrical output 142. Also, a meter 160 (e.g., a voltmeter, ammeter, wattmeter, etc.) may be coupled to the electrical output 132 (or 142) to provide a feedback signal 162 to the control circuitry 150. Other meters or indicators (not shown) may also be provided, such as an indicator to displaying the remaining amount of energy remaining in the generator 100.
In operation, the neutron source 120 receives the activation signal 152. In response to receiving the activation signal 152, the neutron source 120 generates neutrons 122, which impinge upon the fuel sample 110. The neutrons 122 convert atoms of Bi209 in the fuel sample to Bi210. A radioactive decay process ensues whereby atoms of Bi210 decay to Po210, which in turn decay into Pb206, releasing alpha particles and heat 114. The set of thermoelectric converters 130 convert energy of the heat 114 to energy of electricity 132. Power management 140 may optionally regulate the electricity 132 (e.g., to produce stable output voltage). In some examples, multiple thermoelectric converters 130 are used, and the power management 140 may further combine outputs to form series and/or parallel output combinations. Further, multiple generators like the generator 100 may be used in combination, with the power management 140 operating to regulate and/or combine electricity 132 from different generators 100.
Other materials besides Bi209 may be used in the fuel sample 110, such as Bi208. However, Bi208 reacts much more slowly than Bi209, owing to the fact that Bi209 must gain two neutrons before it can decay into Po210 and then into lead. In addition, catalysts such as Beryllium (Be) may be added to the fuel sample 210 to amplify neutron generation initiated by the neutron source 120. In an example, the beryllium is formed in a thin film coating over the Bi209.
In some examples, the control circuitry 150 is coupled to the neutron source 120 to provide the activation input 152 to the neutron source 120 and thereby to initiate the radioactive decay reactions in the fuel sample 110 and conversion of thermal energy to electrical energy 132 on demand. The control circuitry 150 may be implemented with a microcontroller or microprocessor; however, this is not required. For example, the control circuitry 150 can be as simple as a switch that applies a voltage to the neutron source 120 to initiate neutron emission. For example, a switch can be placed on an exterior wall of the generator 100 and a human operator or some mechanical device can actuate the switch to initiate emission of neutrons 122. In some arrangements, a switch may be provided as part of the neutron source 120 itself, such that no additional switch is used.
When implemented as a microcontroller or microprocessor, the control circuitry 150 may generate the activation input 152 electronically (e.g., via program code running in the control circuitry 150), and may provide the activation input 152 in the form of a pulse having a pulsewidth 154. In an example, the activation input 152 is an electronic signal having an initially LOW state corresponding to an OFF condition of the neutron source 120 and a HIGH state corresponding to an ON condition of the neutron source 120. The control circuitry 150 changes the state of the activation input 152 from LOW to HIGH to activate the neutron source 120 and later from HIGH to LOW to deactivate the neutron source 120. The duration of the pulsewidth 154 establishes a particular dose of neutrons 122, with different durations of the pulsewidth 154 causing the neutron source 120 to emit different doses. The amount of heat 114 emitted from the fuel sample 110 varies in relation to the neutron dose, with more heat 114 being emitted in response to higher doses. Thus, by establishing a particular pulsewidth 154 of the activation input 152, the control circuitry 150 causes the generator 100 to produce a certain amount of power, which is generally predicable given known starting parameters. By varying the pulsewidth 154 of the activation input 152, the control circuitry 150 causes the generator 100 to generate different amounts of power. It should be understood that some implementations of the neutron source 120 provide greater neutron emission in response to larger amplitudes of the activation input 152. In such examples, the control circuitry 150 may further vary the amplitude of the activation input 152 to provide further control over output power.
In some examples, a given initial dosage of neutrons 122 is enough to initiate radioactive decay reactions in the fuel sample 110 but only partially to consume the fuel sample 110. Thus, depending on the amount of Be or other catalysts present, the decay reactions in the fuel source 110 may be self-limiting. The control circuitry 150 may thus be configured to assert the activation input 152 a second time or repeatedly to reactivate the fuel sample and provide additional electrical output from the generator 100.
In some examples, the meter 160 is coupled to the set of thermoelectric converters 130 to measure the electrical output 132. The meter 160 is further coupled to the control circuitry 150 to provide a feedback signal 162 to the control circuitry 150. The feedback signal 162 varies in relation to the electrical output 132, and the control circuitry 150 is configured to detect, based on the feedback signal 162, when the electrical output 132 drops below a predetermined level. When such detection is made, the control circuitry 150 again provides the activation input 152 to the neutron source 120 to reactivate the fuel sample 110 and increase the electrical output 132. Eventually, the fuel sample 110 will become spent, but it is envisaged that monitoring the electrical output 132 and reactivating the fuel sample 110 can extend service life of the generator 100 significantly.
In some examples, the control circuitry 150 is coupled to the communication receiver 170 to receive commands from a remote system (not shown). For example, the generator 100 may be deployed on a space vehicle and the remote system may be a ground based control center. The remote system transmits a remotely generated activation signal 172, which the communication receiver 170 receives and hands off to the control circuitry 150. When the control circuitry 150 receives the remotely generated activation signal 172, the control circuitry 150 proceeds to generate the activation signal 152 to activate the fuel sample 110 and initiate (or re-initiate) power generation.
The fuel sample 110 of the generator 200 is seen to include multiple portions, P1, P2, P3, and P4, and the neutron source 120 is seen to be moveable, e.g., along a track or rail 210 and along direction 220, to assume any of positions 120a, 120b, 120c, or 120d, to expose the portions P1 to P4 to neutrons 122. Alternatively (or in addition), the fuel sample 110 may itself be moveable, e.g., along a track or rail (not shown) and along direction 230, to expose the different portions P1 to P4 to neutrons 120 emitted from the neutron source 120.
In example operation, the control circuitry 150 directs movement of the neutron source 120 (e.g., by a motor or other actuator) to position 120a and asserts the activation input 152, thereby causing the neutron source 120 to emit neutrons 122 into the first portion P1 of the fuel sample 110. The neutrons 122 initiate radioactive decay in the first portion P1, which generate heat 114, and the thermoelectric converter(s) 130 convert the heat 114 to electricity 132.
Later, the control circuitry 150 directs movement of the neutron source 120 to position 120b, where the neutron source 120 emits neutrons 122 into portion P2. Similar actions can be repeated for positions 120c and 120d, exposing portions P3 and P4 to neutrons 122 and inducing radioactive decay in the respective portions.
In some examples, the control circuitry 150 exposes the different portions P1 to P4 to neutrons 122 based on a predetermined sequence and with predetermined timing. For example, the control circuitry 150 may advance the neutron source 120 to the next position every 138 days (the half-life of Po210) to expose the next portion to neutrons. The lifespan of the generator 200 may thus be prolonged greatly by sequentially initiating radioactive decay in the different portions P1 to P4. The control circuitry 150 may vary the pulsewidth 154 (and/or amplitude) of the activation input 152, as described above, for generating different levels of output power. Also, the control circuitry 150 may move the neutron source 120 and expose the next portion to neutrons more or less frequently than the 138 days stated above, to adjust output power.
In some examples, the generator 200 operates with feedback, wherein the control circuitry 150 monitors the feedback signal 162 and advances the neutron source 120 to the next position to activate the next portion of the fuel sample 110 when the feedback signal 162 indicates that the electrical output 132 has fallen below a predetermined threshold.
Although the fuel sample 110 is shown as having a rectangular shape with portions P1 to P4 arranged along a line, those skilled in the art would recognize that many different shapes can be used for the fuel sample 110 and its portions and that no particular geometrical arrangement is required. The one shown is merely illustrative.
At step 1010, an activation input is received. For example, the neutron source 120 receives the activation input 152.
At step 1012, a neutron source is activated to irradiate a fuel sample with neutrons to initiate radioactive decay reactions in the fuel sample to generate heat. For example, the neutron source 120 is activated to irradiate the fuel sample 110 with neutrons 122 to initiate radioactive decay reactions in the fuel sample 110 to generate heat 114.
At step 1014, the heat from the radioactive decay reactions is converted to electrical energy. For example, the thermoelectric converter(s) 130 convert the heat 114 to electrical energy 132.
Improved techniques have been described in which a thermoelectric generator employs a safe, initially dormant, stable, non-radioactive fuel sample which is activated on-demand by a neutron source which initiates and controls activation of the fuel sample. The improved technique allows thermoelectric generators to be fully assembled and stored for extended periods of time before they are deployed for use, and then activated on demand only when the need arises for them to generate power.
Having described certain embodiments, numerous alternative embodiments or variations can be made. For example, although
Also, the neutron source 120 (and sources 120(1-3)) may be of any suitable type and may emit neutrons 122 in any suitable radiation pattern, such as in a pencil beam, a fan beam, a conical pattern, a cylindrical pattern, or any pattern.
Further, any of the thermoelectric generators described above may be used both to generate electricity and to generate heat. Heat 114 that is not converted to electrical energy may thus be used to heat the environment in which the generator is deployed.
Further, although features are shown and described with reference to particular embodiments hereof, such features may be included and hereby are included in any of the disclosed embodiments and their variants. Thus, it is understood that features disclosed in connection with any embodiment are included as variants of any other embodiment.
As used throughout this document, the words “comprising,” “including,” and “having” are intended to set forth certain items, steps, elements, or aspects of something in an open-ended fashion. Also, as used herein and unless a specific statement is made to the contrary, the word “set” means one or more of something. Although certain embodiments are disclosed herein, it is understood that these are provided by way of example only and the invention is not limited to these particular embodiments.
Those skilled in the art will therefore understand that various changes in form and detail may be made to the embodiments disclosed herein without departing from the scope of the invention.
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Number | Date | Country | |
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20150357067 A1 | Dec 2015 | US |