The present disclosure relates to combined heat and power systems.
The statements in this section merely provide background information related to the present disclosure and may not constitute prior art.
Combined heat and power (“CHP”)—also known as co-generation—refers to the generation of heat and electrical power in the same device or location. In CHP, excess heat from local electrical power generation is delivered to the end-user, thereby resulting in higher combined efficiency than separate electrical power and heat generation. Because of the improvement in overall efficiency, CHP can offer energy cost savings and decreased carbon emissions.
Micro-CHP involves devices producing less than approximately 50 kW of electricity. Micro-CHP has not been widely adopted at power levels of less than approximately 5 kW electricity, despite the vast majority of households in North America and Europe having average demand of 1 kW of electricity or less. This limitation in adoption of micro-CHP is based on a combination of technology and economics. For example, no currently known technology offers a suitable combination of the following characteristics at scales below approximately 5 kW: low capital cost; low or no noise (that is, silent operation); no maintenance for long periods of time; ability to ramp on/off quickly to follow heat usage loads; competitive efficiencies at small scales; and integrability with home heating appliances such as furnaces (for heating air), boilers/water heaters (for heating water), and/or absorption chillers (for providing cooling) (known as “heating units” or “home heating appliances” or the like).
CHP works in two modes. One mode is heat-following mode, in which generating heat is the primary function of the system and electricity is produced whenever heat is in demand by diverting some of the heat into the production of electricity. The other mode is electricity-following, in which the principle function of the system is to produce electricity and the heat produced in the process of generating the electricity is captured for another useful purpose, such as heating water or providing heat for a secondary process.
The higher the utilization rate (that is, on-time) of the electricity generator, the better the economic payback for a micro-CHP unit in heat-following mode. It is desirable to balance the heat load and the demand for electricity. In a CHP device, it is also desirable to transfer waste heat efficiently from the heat engine to air or water. Efficient heat transfer can entail high-quality heat exchangers as well as good thermal/mechanical coupling between the heat engine and the heat exchangers.
Various disclosed embodiments include combined heating and power modules and combined heat and power devices.
In an illustrative embodiment, a combined heat and power module includes at least one burner. At least one thermophotovoltaic converter is thermally couplable to the at least one burner, the at least one thermophotovoltaic converter having photon emitter, the photon emitter being configured to be thermally couplable to the at least one burner, and at least one photovoltaic cell being configured to be thermally couplable to a heat exchanger.
In another illustrative embodiment, a combined heat and power module includes at least one burner. At least one thermophotovoltaic converter has a photon emitter and at least one photovoltaic cell and the photon emitter is configured to be thermally couplable to the at least one burner. A heat exchanger is configured to be thermally couplable to the at least one photovoltaic cell. Each one of the at least one burner and the at least one thermophotovoltaic converter and the heat exchanger is thermally couplable to at least one other of the at least one burner and the at least one thermophotovoltaic converter and the heat exchanger.
In another illustrative embodiment, a combined heat and power device includes a heating system including: at least one burner; at least one igniter configured to ignite the at least one burner; a fluid motivator assembly including an electrically powered prime mover; and a heat exchanger fluidly couplable to the fluid motivator assembly. At least one thermophotovoltaic converter has a photon emitter and at least one photovoltaic cell, the photon emitter being thermally couplable to the at least one burner, the at least one photovoltaic cell being thermally couplable to the heat exchanger.
In another illustrative embodiment, a combined heat and power device includes a heating system including: at least one burner; at least one igniter configured to ignite the at least one burner; a fluid motivator assembly including an electrically powered prime mover; and a heat exchanger fluidly couplable to the fluid motivator assembly. At least one thermophotovoltaic converter has a photon emitter and at least one photovoltaic cell, the photon emitter being thermally couplable to the at least one burner, the at least one photovoltaic cell being thermally couplable to the heat exchanger. An electrical battery is electrically connectable to the at least one igniter and the prime mover.
In another illustrative embodiment, a combined heat and power device includes a heating system including: at least one burner; at least one igniter configured to ignite the at least one burner; a fluid motivator assembly including an electrically powered prime mover; and a heat exchanger fluidly couplable to the fluid motivator assembly. At least one thermophotovoltaic converter has a photon emitter and at least one photovoltaic cell, the photon emitter being thermally couplable to the at least one burner, the at least one photovoltaic cell being thermally couplable to the heat exchanger. The thermophotovoltaic converter is electrically couplable to the prime mover.
The foregoing summary is illustrative only and is not intended to be in any way limiting. In addition to the illustrative aspects, embodiments, and features described above, further aspects, embodiments, and features will become apparent by reference to the drawings and the following detailed description.
Illustrative embodiments are illustrated in referenced figures of the drawings. It is intended that the embodiments and figures disclosed herein are to be considered illustrative rather than restrictive.
In the following detailed description, reference is made to the accompanying drawings, which form a part hereof. In the drawings, similar symbols typically identify similar components, unless context dictates otherwise. The illustrative embodiments described in the detailed description, drawings, and claims are not meant to be limiting. Other embodiments may be utilized, and other changes may be made, without departing from the spirit or scope of the subject matter presented here.
By way of overview, various disclosed embodiments include combined heating and power modules and combined heat and power devices. As will be explained in detail below, in various embodiments illustrative combined heating and power modules include, among other things, at least one thermophotovoltaic converter and are suited to be disposed in a heating appliance such as, for example, a furnace, a boiler, or a water heater. As will also be explained in detail below, in various embodiments illustrative combined heating and power devices include, among other things, at least one thermophotovoltaic converter and are suited for use as a heating appliance such as, for example, a furnace, a boiler, or a water heater. Thus, it will be appreciated that various embodiments can help contribute to seeking to increase the electricity: heat ratio in a combined heat and power (“CHP”) or co-generation device.
Now that a non-limiting overview has been given, details will be explained by way of non-limiting examples given by way of illustration only and not of limitation.
Referring to
In various embodiments the thermophotovoltaic converter 14 may be used in a combined heat and power (CI-IP) system and may include the photon emitter 16 and the photovoltaic cells 18 which may be thermally couplable to a heat exchanger 72. It will be appreciated that the photon emitter 16 desirably would provide narrowband radiation with an energy just above the bandgap of PV cells (not shown) in the photovoltaic converters 14—because photon energies much higher than this may entail a risk of overheating of the PV cell(s). To that end, the photon emitter 16 and/or the PV cells 18 may be coated with a particular material or optical metamaterial to reflect or transmit wavelengths of light selectively.
In various embodiments, the thermophotovoltaic converter 14 may include the photon emitter 16 and more than one of the photovoltaic (PV) cells 18. The individual PV cells 18 may be arranged as tiles, and may be mounted directly on a heat exchanger 72. The individual PV cells 18 may be arrayed electrically in series or in parallel.
In various embodiments, the thermophotovoltaic converter 14 may include an enclosed device wherein the atmosphere is controlled between the photon emitter 16 and the photovoltaic (PV) cells 18. The atmosphere may include one or a mixture of an inert gas, such as argon or nitrogen or a halogen. Such embodiments can help reduce, minimize, or possibly prevent accumulation of material evaporated or sublimated from the photon emitter 16 on the photovoltaic cells 18. In some such embodiments, the gas may chemically recycle material evaporated from the photon emitter 16 back to the photon emitter 16 via “halogen cycle” chemical vapor transport. In some other embodiments, pressure of the gas may be tuned from vacuum to above atmospheric pressure to help reduce or minimize conductive or convective heat transfer from the hot photon emitter 16 to the colder photovoltaic cells 18. In such embodiments, tuning the pressure of the gas from vacuum to above atmospheric pressure also may reduce or minimize material accumulation on the photovoltaic cells 18 as the material sublimes or evaporates from the photon emitter 16. In such embodiments, use of high pressure gas entails a physical (as opposed to chemical) mechanism. That is, material evaporated from the photon emitter 16 will scatter off the gas back to the photon emitter 16. Thus, tuning the pressure of the gas from vacuum to above atmospheric pressure may suppress transport of material evaporated from the photon emitter 16 to the photovoltaic cells 18.
In various embodiments, the photon emitter 16 may include graphite, silicon carbide, tungsten, tantalum, niobium, molybdenum, aluminum oxide, zirconium oxide, or a combination or coatings thereof.
Referring additionally to
It will be appreciated that, because the photovoltaic cells 18 are configured to be thermally couplable to a heat exchanger, the module 10 is suited for use in a heating appliance such as, without limitation, a furnace, a boiler, or a water heater in settings such as a residence or a commercial building, and can help contribute to increasing overall system efficiency by using waste heat from the photovoltaic cells 18 for a useful purpose such as space or water heating.
Thus, it will be appreciated that the module 10 can replace an existing boiler or gas furnace burner and can thereby allow an existing boiler/gas-furnace to be retrofitted to a combined heat and power device. The functional zones of the thermophotovoltaic converter 14 (that is, the photovoltaic cell(s) 18 can be formed to maximize power production and minimize the overall volume of the thermophotovoltaic converter 14. In addition, the burner 12 can be designed to work at the same gas and air pressure as the existing burner, thereby allowing the inlet fuel pressure and air delivery system of existing boiler/gas furnaces to be used. By creating an exhaust stream that is similar to that of the existing burner (such as, for example, flow, temperature, exhaust manifold size and connections), no further changes need be made to an existing boiler/gas furnace.
It will be appreciated that operating temperature of the photon emitter 16 is high. Because of its high temperature, the photon emitter 16 can lose a significant amount of energy to an appliance's environment (typically walls of a heat exchanger) through radiation. This loss can be a challenge especially for the walls of the heat exchanger that do not face the flame.
To help contribute to reducing heat loss from the side of the photon emitter 16, in some embodiments and as shown in
As also shown in
As shown in
It will be appreciated that any number of burners 12 may be used in the module 10 as desired for a particular application. For example, in some embodiments the module 10 may include no more than one burner 12. However, in some other embodiments the module 10 may include more than one burner 12.
In various embodiments the burner 12 may be configured to combust with preheated air/fuel (that is, recuperation of enthalpy of exhaust gas of the burner 12 by preheating air/fuel) or using an enrichment agent such as oxygen-enriched air or hydrogen-enriched combustion. In some such embodiments, flame temperatures—and thus potentially photon emitter temperatures—can be increased by firing with preheated air/fuel or oxygen-enriched air to aid with heat transfer from the flame or flue gas to the photon emitter. Given by way of non-limiting example, firing with oxygen-enriched air can be accomplished by use of an oxygen concentrator/enrichment system and using this oxygen in the input stream of the burner 12. It will be appreciated that pure oxygen need not be used. For example, with use of pressure-swing-absorption-processed air (“PSA”), as little as two-fold boosting of oxygen concentration may be adequate to accomplish firing with oxygen-enriched air. Given by way of another non-limiting example, a “rapid PSA” device (that operates more isentropically) may be used as desired for a particular application. It may also be desirable to exhaust such relatively high-temperature gases quasi-adiabatically—and/or over a suitably-catalytic surface—in order to suppress NOx emissions. It will be appreciated that use of oxygen in the flame in some operating conditions can also have the effect of lowering NOx emissions despite the increased flame temperature (due to proportionally lower availability of N2 from air).
In some other such embodiments, hydrogen-enriched combustion may also result in higher flame temperatures which will help with heat transfer from the flame or flue gas to the photon emitter. In such embodiments, hydrogen-enriched combustion can be accomplished by including a device upstream on the fuel line that cracks incoming fuel (such as natural gas or methane) into hydrogen, thereby leaving behind carbon. This hydrogen is fed into the flame to raise flame temperature, thereby enhancing heat transfer from the flame or flue gas to the thermophotovoltaic converter 14. The hydrogen may be readily sourced by decomposition or partial oxidation of the input natural gas (or methane) stream. It will be noted that methane is thermo-fragile and reasonably-readily decomposes into elemental carbon and molecular hydrogen. Given by way of non-limiting example, a suitable arrangement can include a (micro-)finned heat exchanger through which the methane is flowed toward the eventual combustion-region, with its hot side heated by exhausted combustion gas. Natural gas thereby refined from (most all of) its carbon content is then burned as a stream of relatively-pure hydrogen, with the carbon remaining behind in the cracking unit. It will be appreciated that, as in the oxygen-enriched air case, pure hydrogen need not be used. In some embodiments, this cracking unit may be regenerated periodically—that is, its accumulated carbon-load removed—by valving heated air (and perhaps a small amount of natural gas for ignition purposes) through it, thereby recovering the latent heat of the carbon for use downstream (for example, the primary space-or-water-heating purposes)—with a twin cracking unit being exercised in its place during this alternating split-cycle operation. Thus, in such embodiments higher temperature flame can be produced than in classic near-stoichiometric hydrogen-oxygen combustion.
In some other embodiments, instead of fully decomposing natural gas or methane and removing carbon content for pure hydrogen combustion, preheating and decomposing the fuel (such as natural gas, methane, or propane) without carbon removal can lead to an enhancement in flame emittance which can help enhance heat transfer from the flame or flue gas to the photon emitter by increasing radiation to the thermophotovoltaic converter 14 and can help limit localized flame hot-spots and, therefore, NOx emissions.
In some embodiments the burner 12 may be configured for substantially stoichiometric combustion. In some such embodiments it may be advantageous to burn additional fuel (and, in some cases, possibly air) close to the photon emitter 16 and closer to the stoichiometric mixture for enhanced heat transfer (that is, a higher flame temp) from the flame or flue gas to the photon emitter. Because in some instances the thermophotovoltaic converter 14 may only be using a small amount (such as around five percent or so) of the total thermal power of a heating appliance such as a furnace or boiler, it is possible that the NOx increase is not significant enough to impact the rating of the systems. In some instances, only the portion of the burner 12 that provides the majority of the thermal power for heating the water (in a boiler or water tank) or the air (in a furnace) could run slightly leaner to reduce NOx to accommodate for the localized increase in NOx at or near the surface of the photon emitter 16.
In various embodiments, the thermophotovoltaic converter 14 has an electrical power output capacity of no more than 50 kWe. In some such embodiments, the thermophotovoltaic converter 14 has an electrical power output capacity of no more than 5 kWe. In either case, it will be appreciated that the thermophotovoltaic converter 14 (and, as a result, the module 10) is suited for use in a heating appliance such as, without limitation, a furnace, a boiler, or a water heater in settings such as a residence or a commercial building.
In various embodiments the outer surface of the photon emitter 16 may be coated with a material that is configured to increase thermal emissivity, thereby increasing heat transfer to the thermophotovoltaic converter 14. In such embodiments, the material may include any suitable material such as silicon carbide, carbon, an inorganic ceramic, a silicon ceramic, a ceramic metal composite, a carbon glass composite, a carbon ceramic composite, zirconium diboride, “black” alumina (aluminum oxide with addition of magnesium oxide), or a combination thereof. It will be appreciated that the material may be tuned or roughened to increase radiative heat transfer from the burner 12 to the photon emitter 16.
It will be appreciated that various thermophotovoltaic converters 14 can operate at lower hot side temperatures and lower photovoltaic cell temperatures than other types of heat engines, thereby allowing use of more affordable ceramic components and also allowing for integration into water-based heat exchangers (because the heat rejection temperature is closer to the boiling point of water). This allows the thermophotovoltaic converter 14 to potentially be immersed in water for more efficient water heating.
Referring additionally to
The burner 12 and the thermophotovoltaic converter 14 have been discussed in detail above and details of their construction and operation need not be repeated for an understanding by one of skill in the art. It will also be appreciated that heat exchangers are well known in the art and details of their construction and operation need not be discussed for an understanding by one of skill in the art.
It will be appreciated that, because the photovoltaic cells 18 are configured to be thermally couplable to the heat exchanger 72, the module 70 is suited for use in a heating appliance such as, without limitation, a furnace, a boiler, or a water heater in settings such as a residence or a commercial building, and can help contribute to increasing overall system efficiency by helping to use waste heat from the photovoltaic cells 18 (as indicated by arrows 74) that is thermally couplable to the heat exchanger 72 in a heating appliance.
In some embodiments the photovoltaic cells 18 and the heat exchanger 72 may be arranged such that the photovoltaic cells 18 and the heat exchanger 72 physically contact each other. Referring additionally to
However, it will be appreciated that the photovoltaic cells 18 and the heat exchanger 72 need not physically contact each other. To that end, in some other embodiments the photovoltaic cells 18 and the heat exchanger 72 are spaced apart from each other. That is, the photovoltaic cells 18 and the heat exchanger 72 may be arranged such that the photovoltaic cells 18 and the heat exchanger 72 do not physically contact each other. In such embodiments, heat may be transferred from the photovoltaic cells 18 to the heat exchanger 72 via convection.
Referring additionally to
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The burner 12 and the thermophotovoltaic converter 14 have been discussed in detail above and details of their construction and operation need not be repeated for an understanding by one of skill in the art. It will also be appreciated that heat exchangers are well known in the art and details of their construction and operation need not be discussed for an understanding by one of skill in the art. Also, thermal coupling between burner 12 and the thermophotovoltaic converter 14 and between the thermophotovoltaic converter 14 and the heat exchanger 72 have been discussed in detail above and their details need not be repeated for an understanding by one of skill in the art.
In some embodiments the burner 12 and the thermophotovoltaic converter 14 may be installed in the combined heat and power device 80 as the module 10. However, in some other embodiments the burner 12 and the thermophotovoltaic converter 14 may be installed individually in the combined heat and power device 80. Similarly, in some embodiments heat exchanger 72 may be installed in the combined heat and power device 80 as part of the module 70. However, in some other embodiments the heat exchanger 72 may be installed individually in the combined heat and power device 80.
Referring additionally to
In embodiments in which the combined heat and power device 80 includes a furnace (
In embodiments in which the combined heat and power device 80 includes a boiler (
In embodiments in which the combined heat and power device 80 includes a boiler (
Referring additionally to
In various embodiments a temperature sensor 92 is configured to sense temperature of the thermophotovoltaic converter 14 and at least one electricity sensor 94 is configured to sense electrical output (that is, voltage and/or current) of the thermophotovoltaic converter 14. Output signals from the temperature sensor 92 and the electricity sensor 94 are provided to the controller 90. In some embodiments output signals from the temperature sensor 92 and the electricity sensor 94 may be provided to a transceiver 96 that is configured to transmit and receive data regarding the temperature sensor 92 and the electricity sensor 94.
It will be appreciated that the combined heat and power device 80 enabled with the temperature sensor 92 and the electricity sensor 94 can collect data on heat and electricity output. It will also be appreciated that the controller 90 is configured to process the data for optimization. That is, the combined heat and power device 80 can draw inferences on the time-and-magnitude of usage patterns and can help toward optimizing its future behavior (for example, to pre-heat the building at predicted times—such as before an occupant or employee usually returns).
It will also be appreciated that the combined heat and power device 80 enabled with the temperature sensor 92 and the electricity sensor 94 can transmit data wirelessly to-and-from other electricity-consuming devices in the building (such as, for example, an electric car, air conditioner and HVAC, smart home hubs, smart home assistants, and the like) so that these devices can modulate their own or other device's utilization of electricity and so that the electricity and heat demand of the building more closely matches the supply of electricity and heat from the combined heat and power device 80.
It will also be appreciated that the combined heat and power device 80 enabled with the temperature sensor 92 and the electricity sensor 94 can transmit data wirelessly to-and-from the electric utility and/or regulator. As a result, electricity generation can be scheduled in advance or can be dispatched on command such that the produced electricity is fed in reverse through an electrical meter back onto the grid.
Finally, it will also be appreciated that output from a thermophotovoltaic converter is a function of temperature of the surfaces of the emitter (photon emitter) and photovoltaic cells. Over time, the performance of a boiler and gas furnace is reduced because of changes in the combustion system and heating surface—for instance because of fouling of components. Multiple components may be susceptible to these degradations. In the combustion system, for example, degradation of the blower can reduce combustion air flow. This reduction in combustion air flow may increase the flame temperature and, as a result, the power output from the thermophotovoltaic converter. In the heat exchanger, fouling of the heating surfaces lowers the temperature of the heating fluid because the total heat transfer is lowered. Additionally, the heat up rate of the building or hot water supply is impacted by changes to these system components. After prolonged use of the combined heat and power device 80, the time it will take the combined heat and power device 80 to heat the heating fluid will change. Because the thermophotovoltaic converter 14 is connected to both the heating and cooling portion of the combined heat and power device 80, the degradation of the heating demand response can be determined without the use of any thermocouples. As is known, thermocouples only measure a local temperature—whereas the thermophotovoltaic converter provides a more global visibility of the impact on temperature variations. In some systems, then, the temperature monitoring of the system can be enhanced with monitoring the performance of the thermophotovoltaic converter 14 instead of or in addition to the use of thermocouples or other sensors.
In various embodiments the controller 90 is further configured to modulate electricity output from the thermophotovoltaic converter 14. In some such embodiments the controller 90 modulates electricity output from the thermophotovoltaic converter 14 based upon an attribute such as a number of burners 12 and/or a number of thermophotovoltaic converter 14. For example, in some embodiments the combined heat and power device 80 may include multiple burners 12 and multiple thermophotovoltaic converters 14, and one or more of the burners 12 may not be thermally coupled to any of thermophotovoltaic converters 14. In some such embodiments the controller 90 is further configured to turn on burners 12 that are thermally couplable to thermophotovoltaic converters 14 before turning on burners 12 that are not thermally couplable to thermophotovoltaic converters 14. Likewise, in some embodiments the controller 90 is further configured to turn off burners 12 that are not thermally couplable to thermophotovoltaic converters 14 before turning off burners 12 that are thermally couplable to thermophotovoltaic converters 14. It will be appreciated that such a scheme increases utilization time and can help spread out the occurrence of wear and tear on each individual thermophotovoltaic converter 14, thereby helping contribute to prolonging overall system lifetime and maximizing economic value proposition.
In various embodiments the controller 90 is configured to modulate electrical power output of the thermophotovoltaic converter 14 at a power point that differs from a maximum power/efficiency point on a current-voltage profile of the thermophotovoltaic converter 14.
In some embodiments the controller 90 may be further configured to modulate the burner 12 (also known as “turndown”) when little heat is desired. In such embodiments, the burner 12 can modulate/turndown up to N:1 (that is, operate at 1/N its rated capacity). In some embodiments, the burner 12 may include multiple sub-burners. One or more of these sub-burners can be thermally couplable to an thermophotovoltaic converter 14. The burner 12 with the thermophotovoltaic converter 14 could operate at 1/N of its rated capacity and keep the thermophotovoltaic converter 14 hot, thereby generating electricity the entire time, thereby resulting in a higher utilization rate. In such embodiments the controller 90 may be further configured to turn all burners 12 at maximum capacity to provide desired heating quickly. Then, when the desired temperature is reached and less heat is desired, the controller 90 turns off all but one burner 12 which stays on preferentially to keep the thermophotovoltaic converter 14 hot, thereby generating electricity the entire time and resulting in a higher utilization rate.
In some embodiments the controller 90 can be configured for multi-cell thermophotovoltaic converter modulation. For example, there may be instances in which less electricity is needed at a given time, or it is cheaper to buy electricity from the grid, or batteries are fully charged (or some other scenario where it is not desired to generate electricity with the thermophotovoltaic converter 14.
Thus, it will be appreciated that modulation can help contribute to matching demand in the building (as indicated by a smart home-type controller that may or may not be connected to receive information about energy use in the building or on the electricity or fuel grids). It will also be appreciated that modulation can help contribute to tuning the heat: electricity ratio and can turn up/down depending on the amount of heat desired. It will also be appreciated that modulation can help increase (with a goal of maximizing) economic return, such as by turning on only a burner 12 with an associated thermophotovoltaic converter 14 to sell electricity back to the larger electricity grid (if heat is not desired but the goal is to maximize money) and excess heat could be stored in a tank/storage battery of some sort (such as a hot water tank).
In various embodiments power electronics 98 are electrically coupled to the thermophotovoltaic converter 14. In various embodiments the power electronics 98 is configured to boost DC voltage (via a DC-DC boost converter 124) and/or invert DC electrical power to AC electrical power (via a DC-AC inverter 122). Because output voltage from the thermophotovoltaic converter 14 is relatively low, the power electronics 98 boost output voltage from the thermophotovoltaic converter 14 to useful voltages. The DC-AC inverter 122 transforms the boosted DC voltage to an AC voltage in order to export power to the building, or to run AC driven boiler/furnace components, or to transfer power to the local electrical grid outside the building.
In various embodiments inlet air to the burner 12 and/or inlet fuel to the burner 12 may be pre-heated. In some embodiments the power electronics 98 are disposed in thermal communication with inlet air to the burner 12 and/or inlet fuel to the burner 12. Loss of efficiency in the power electronics 98 can be recovered by using inlet air to the burner 12 and/or inlet fuel to the burner 12 as a cooling stream for the power electronics 98. Lost heat will then be passed into the intake stream, which preheats it and is recovered. By locating the power electronics 98 in or near the incoming stream of air and/or fuel, the heat lost in the power electronics 98 can be used to preheat the intake air, thereby recapturing some of this energy that would otherwise be lost.
In some embodiments a recuperator 100 is configured to pre-heat inlet air to the burner 12 and/or inlet fuel to the burner 12 with exhaust gas from the burner 12.
In various embodiments the combined heat and power device 80 is configured to be electrically couplable to an electrical bus transfer switch.
In various embodiments a resistive heating element is electrically connectable to the thermophotovoltaic converter 14. In some embodiments it may be desirable to use the excess power that is produced by the thermophotovoltaic converter 14 (that is, electricity produced in excess to the load demand by the building grid) and send that power to a resistive heater. It will be appreciated that the full energy production potential from the thermophotovoltaic converter 14 may be substantially used and that modulation is not required.
In various embodiments the combined heat and power device 80 can be operated to produce higher electricity output to meet high electricity demand. In some of these cases, more heat may be generated than is desired at a given time. In such instances, the excess heat can be handled by at least the following: (i) attach a hot water tank to take the excess heat, thereby storing the heat for space heating or hot water that can be delivered later; (ii) attach phase change material to take some of the excess heat, thereby storing the heat for space heating or hot water than can be delivered later; (iii) attach an absorption cycle cooling system to take the excess heat and generate cooling; (iv) transmitting a signal to the building air duct system, which can open-or-close an opening to allow the heated air to partially flow outside the building; and (v) direct the excess heat flow into the flue gas exhaust tube of the combined heat and power device 80 via a controllable valve.
It will also be appreciated that the combined heat and power device 80 can use external data including weather, real-time and future (day-ahead) energy market prices, utility generation forecast, demand forecast data, or externally- (cloud-) computed algorithms based on such data to help optimize use of the thermophotovoltaic converter 14 or to help create optimized economic value for the owner of the building or external parties (such as utilities or energy service companies).
It will also be appreciated that multiple combined heat and power devices 80 (such as in different buildings and/or across geographies) can be aggregated and controlled (either through the internet and/or wireless networks) in tandem to provide grid ancillary services that can help contribute to offering more value to utilities and grid operators than a single combined heat and power device 80 alone. For example, a utility seeing a dangerous spike in energy demand on a specific substation could switch on and control all thermophotovoltaic converters in the distribution grid for that substation, thereby reducing demand for each home and, thus, reducing the load on the substation or distribution grid. Similarly, other grid services may be provided, including capacity, voltage and frequency response, operating reserves, black start, and other compensated services.
Referring additionally to
In such embodiments, the combined heat and power device 110 includes a heating system 82. The heating system 82 includes at least one burner 12, at least one igniter 84 configured to ignite the at least one burner 12, a fluid motivator assembly 86 including an electrically powered prime mover 88, and the heat exchanger 72 fluidly couplable to the fluid motivator assembly 86. At least one thermophotovoltaic converter 14 has a photon emitter 16 and photovoltaic cells 18. The photon emitter 16 is thermally couplable to the burner 12 and the photovoltaic cells 18 are thermally couplable to the heat exchanger 72. An electrical battery 112 is electrically connectable to the igniter 84 and the prime mover 88 and system controls.
From a cold start, the electrical battery 112 powers the igniter 84 and the prime mover 88 and system controls. After startup, the thermophotovoltaic converter 14 powers the prime mover 88 and system controls and recharges the electrical battery 112.
In some embodiments a battery connection controller 114 is configured to electrically connect the electrical battery 112 to the igniter 84 and the prime mover 88 and system controls. In some such embodiments the battery connection controller 114 may be further configured to electrically connect the electrical battery 112 to the igniter 84 and the prime mover 88 and system controls automatically in response to loss of electrical power from an electrical power grid. In some other such embodiments the battery connection controller 114 may be further configured to electrically connect the electrical battery 112 to the igniter 84 and the prime mover 88 and system controls manually by actuation by a user.
In some embodiments the battery connection controller 114 may be further configured to electrically connect the electrical battery 112 to the thermophotovoltaic converter 14 to charge the electrical battery 112.
In some embodiments the heat exchanger 72 may be configurable to direct fluid disposed therein to an interior environment of a building, ambient environment exterior a building, and/or a thermal storage reservoir, such as for example a water tank.
Thus, in such embodiments, as long as the gas supply is steady (which is more reliable than the electrical grid), the combined heat and power device 110 can run on electrical power from the thermophotovoltaic converter 14 alone. It will be appreciated that the thermophotovoltaic converter 14 is to be sized to power all of the electrical loads of the combined heat and power device 110. Given by way of non-limiting examples, these electrical loads can be in a range of less than 50 W, between 50 W and 200 W, or in some cases more than 200 W—depending on the size and power draws of various components.
Referring additionally to
The electrical components of the combined heat and power device 120 typically range from less than 100 Watts of electrical power, between 100 W and 300 W, or in some cases more than 300 W depending on the size and power requirements of various components (blowers, fans, electronic controls, and the like). By incorporating the thermophotovoltaic converter 14 into the combined heat and power device 120 and interfacing with the burner 12, illustrative disclosed thermophotovoltaic converters 14 can help provide enough power to help keep the combined heat and power device 120 running without any external grid electricity.
In this scenario, the power output from the thermophotovoltaic converter can be conditioned using a combination of DC-DC boost converters (for DC components like control boards) and/or inverters (for AC components like some motors) and similar power electronics. In many newer furnaces, DC motors are replacing AC motors in which case an inverter may not be required. In any case, it is important that the thermophotovoltaic converter needs to be sized to power all of the electrical needs of the heating appliance. This can be as in a range of less than 100 Watts of electrical power, between 100 W and 300 W or in some cases more than 300 W depending on the size and power requirements of the boiling components (blowers, fans, electronic controls, etc.)
In various embodiments, the combined heat and power device 120 includes a heating system 82. The heating system 82 includes at least one burner 12, at least one igniter 84 configured to ignite the at least one burner 12, a fluid motivator assembly 86 including an electrically powered prime mover 88, and the heat exchanger 72 fluidly couplable to the fluid motivator assembly 86. At least one thermophotovoltaic converter 14 has a photon emitter 16 and photovoltaic cells 18. The photon emitter 16 is thermally couplable to the burner 12 and the photovoltaic cells 18 are thermally couplable to the heat exchanger 72. The thermophotovoltaic converter 14 is electrically couplable to the prime mover.
In some embodiments, the combined heat and power device includes a DC-AC inverter 122. In such embodiments, the prime mover 88 includes an AC motor and the prime mover 88 is electrically coupled to receive AC electrical power from the DC-AC inverter 122.
In some embodiments, the combined heat and power device includes a DC-DC boost converter. In such embodiments the controller 90 (
In various embodiments, electrical power output of the thermophotovoltaic converter 14 is at least 100 W.
In some embodiments the combined heat and power device includes the electrical battery 112. In such embodiments the battery connection controller 114 is configured to electrically connect the electrical battery 112 to the igniter 84 and the prime mover 88. In some such embodiments the battery connection controller 114 may be further configured to electrically connect the electrical battery 112 to the thermophotovoltaic converter 14 to charge the electrical battery 112.
While various aspects and embodiments have been disclosed herein, other aspects and embodiments will be apparent to those skilled in the art. The various aspects and embodiments disclosed herein are for purposes of illustration and are not intended to be limiting, with the true scope and spirit being indicated by the following claims.
This application is a continuation-in-part of U.S. patent application Ser. No. 16/794,142 filed Feb. 18, 2020 and entitled “COMBINED HEATING AND POWER MODULES AND DEVICES,” the entire contents of which are hereby incorporated by this reference.
Number | Date | Country | |
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Parent | 16794142 | Feb 2020 | US |
Child | 17155605 | US |