One embodiment is a combustor wall that includes a conductive wall defining an exterior surface, a thermal insulator defining an interior surface configured to lie adjacent to a combustion volume configured to be heated to an elevated temperature and to carry charged particles, and an electrical insulator disposed between the conductive wall and the thermal insulator. The thermal insulator is configured to thermally insulate the electrical insulator from the combustion volume. The electrical insulator is configured to electrically insulate the conductive wall from the thermal insulator and the combustion volume.
In one embodiment, an electrically floating conductive foil is positioned between two layers of the thermal insulator material so as to redistribute any charge that finds its way past the first thermally insulating layer.
According to an embodiment, a combustor includes a furnace wall defining a combustion chamber configured to enclose a combustion reaction, a power supply configured to output a high voltage, and a charger operatively coupled to the power supply and to the combustion chamber. The charger is configured to receive the high voltage from the power supply and to cause the combustion reaction to carry a majority charge. The furnace wall includes a conductive wall, a thermal insulator adjacent to the combustion chamber, and an electrical insulator disposed between the thermal insulator and the conductive wall. The thermal insulator is configured to thermally insulate the electrical insulator from the combustion volume. The electrical insulator is configured to electrically insulate the conductive wall from the thermal insulator and the combustion volume.
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. Other embodiments may be used and/or other changes may be made without departing from the spirit or scope of the disclosure.
The outer volume 106 adjacent to the exterior surface 104 of the conductive wall 102 can be atmospheric and/or a water jacket, for example. The conductive wall 102 can be steel or iron and can be electrically grounded. The electrical insulator 116 is contemplated to include several alternative materials. For example, in one embodiment, the electrical insulator 116 was steatite, also referred to as soapstone. Steatite has a relatively low electrical conductivity that is persistent to relatively high temperatures. Low electrical conductivity at high temperatures can be leveraged to reduce the thickness of the thermal insulating layer 108. Thermal insulating properties of the electrical insulator 116 can similarly be leveraged to reduce the thickness of the thermal insulator 108. In other embodiments, other electrical insulator materials and structures may be used. For example, some electrically insulating materials may be selected for a relatively high dielectric constant (at least at a modulation frequency of the charged particles 114), a melting point or glass transition temperature high enough to avoid degradation, and/or a coefficient of thermal expansion that is relatively well-matched to that of the material in the wall 102 and/or the thermal insulator 108. For example, the electrical insulator 116 may include one or more of polyether-ether-ketone, polyimide, silicon dioxide, silica glass, alumina, silicon, titanium dioxide, strontium titanate, barium strontium titanate, or barium titanate. More electrically conductive (poorer electrically insulating) material options (such as polyimide, polyether-ether-ketone, silicon dioxide, silica glass, or silicon) may be most appropriate for the electrical insulator 116 for embodiments using lower voltages, greater electrical insulator 116 thicknesses, and/or greater thermal insulator 108 thicknesses.
The thermal insulator 108 can be a ceramic fiber, a refractory fiber, and/or a refractory ceramic fiber. For example, the thermal insulator 108 can be a vitreous aluminosilicate fiber. For thermal insulator 108 materials that include binder materials that are relatively lower melt point or higher thermal conductivity, the thermal insulator 108 can be heat treated to remove (“burn off”) the binders. The thermal insulator 108 can additionally or alternatively include cordierite (magnesium iron aluminum cyclosilicate), Mullite (a silicate mineral including Al2O3 and SiO2, as 2Al2O3SiO2 or 3Al2O32SiO2.), alumina, and/or an aerogel. The thermal insulator 108 can be formed as a honeycomb material or having another structure including air gap thermally insulating features.
As described above, the electrical insulator 116 can include steatite or another material having suitable properties. The electrical insulator 116 can be configured as a plurality of continuous planes respectively held by gravity adjacent to the conductive wall 102. Additionally or alternatively, the electrical insulator 116 can be configured as a plurality of tiles. Air gaps between adjacent tiles may provide electrical insulation and reduce the need for close fitting of the tiles. For example, the tiles may be separated from one another by up to 0.25 inch in some installations. In other installations, the tiles are installed within 0.125 inch of one another. In some installations, the tiles are installed within 0.0625 of one another.
In some embodiments, the electrical insulator 116 can include two or more layers of insulating tiles (e.g., soapstone tiles). Tiles in respective layers can be offset from one another to minimize or eliminate any single gap penetrating the entire thickness of the electrical insulator 116 (e.g., a two-layer field of electrically insulating tiles can include tiles centered on every three- or four-corner abutting location on an underlying layer of electrically insulating tiles.
The electrical insulator 116 can be adhered to the conductive wall 102 and/or to adjoining electrical insulator layers by adhesive. In an embodiment, the electrical insulator 116 can be affixed to the conductive wall 102, other layers of the electrical insulator 116, and/or to the thermal insulator 108 by a cementitious material that acts an adhesive. In another embodiment, the electrical insulator 116 can be affixed to the conductive wall 102, other layers of the electrical insulator 116, and/or to the thermal insulator 108 by an adhesive material. In another embodiment, the electrical insulator 116 can be affixed to the conductive wall 102, other layers of the electrical insulator 116, and/or to the thermal insulator 108 by nonconductive hardware. For example, alumina screws or posts (including tensile reinforced alumina screws or posts) can mechanically adjoin the electrical insulator 116 to the conductive wall 102, other layers of the electrical insulator 116, and/or to the thermal insulator 108.
The thermal insulator 108 can include a ceramic fiber, a refractory fiber, and/or a refractory ceramic fiber, according to embodiments. The thermal insulator 108 can be held adjacent to the electrical insulator 116 by gravity. Additionally or alternatively, the thermal insulator 108 can be adhered to the electrical insulator 116 by an adhesive and/or by substantially non-conducting fasteners. In an embodiment, the thermal insulator 108 can include a vitreous aluminosilicate fiber. The thermal insulator 108 can be heat treated to remove binders. The thermal insulator 108 can additionally or alternatively include cordierite, Mullite, alumina, and/or an aerogel. The thermal insulator 108 can be formed as a honeycomb or porous material.
The thermal insulator 108 can be configured, under steady-state conditions, to thermally insulate the electrical insulator 116 sufficiently to maintain at least a 700° F. difference between the combustion volume 112 and the electrical insulator 116. In some embodiments, the thermal insulator 108 may be configured to maintain a 1700° F. difference (steady-state) between the combustion volume 112 and the electrical insulator 116.
In one embodiment, the electrical insulator is configured to inhibit leakage current between the charger 308 and outer wall 102 at elevated temperatures. For example, the electrical insulator is configured to allow a maximum voltage drop across the electrical insulator 116 corresponding to 5% of the voltage between the outer wall 102 and the charger 308. Thus, if 40 kV are applied between the charger 308 and the outer wall 102, then a voltage drop of 2 kV is permitted across the electrical insulator 116.
In an embodiment, the electrical insulator 116 maintains at least 10 megaohms resistance between the combustion volume 112 and the furnace wall 302. In another embodiment, the electrical insulator 116 can maintain at least 100 megaohms of resistance to a grounded furnace wall 102. The conductive wall 102 can be held at an electrical ground such as earth ground.
The power supply 306 can be configured to output a high voltage greater than 1000V magnitude. In another embodiment, the power supply 306 can be configured to output a high voltage equal to or greater than 15 kV in magnitude. The power supply 306 can be configured to output a DC voltage and/or output an AC voltage.
The combustor 300 can be a solid fuel 310 burner. The charger 308 can be configured to output an AC high voltage to the combustion reaction 304. The combustor 300 can include a conductive grate 312 configured to act as a counter electrode to the charger 308. The conductive grate 312 can be galvanically isolated.
As the combustion reaction proceeds, the temperature of the gas within the combustion chamber rises until it reaches a steady-state temperature. The thermal insulation layer thermally insulates the electrical insulation layer and the conductive outer wall such that the temperature of the electrical insulation layer is significantly lower than the temperature within the combustion chamber.
At 504 a ground voltage is applied to the conductive outer layer of the wall of the combustion chamber. Alternatively, a voltage other than ground may be applied to the conductive outer layer of the wall of the combustion chamber. Typically, the conductive outer layer may be held at ground by virtue of its continuity with an external environment and/or via a grounded conductor.
At 506 a high voltage is applied to the charger within the combustion chamber. When the high voltage is applied to the charger in the combustion chamber, gases undergoing the combustion reaction are ionized such that a flame within the combustion chamber carries a majority charge. In this way, the characteristics of the combustion reaction within the combustion chamber can be controlled to have selected characteristics. In one embodiment, the high-voltage applied to the charger is between 1000V and 15,000V. Alternatively, the high-voltage can be higher than 15,000V. The voltage applied to the charger can be an AC voltage, a DC voltage, or any suitable waveform to obtain selected characteristics of the combustion reaction within the combustion chamber.
According to one embodiment, at high temperatures the thermal insulation layer becomes electrically conductive. A portion of the thermal insulation layer can be used as an electrode for further controlling characteristics of the combustion reaction within the combustion chamber. Thus, in one embodiment the process 500 comprises applying ground voltage or a third voltage to the portion of the thermal insulation layer used as an electrode. The voltage can be applied to thermal insulation layer by passing a conductor through an aperture in the conductive outer layer and the electrical insulation layer to the thermal insulation layer.
In one embodiment, the process 500 includes cooling the outer conductive layer of the wall of the combustion chamber by passing water along the outside of the conductive layer of the combustion chamber wall. In this case, a water jacket configuration contains the water as it is passed along the outer conductive layer of the wall of the combustion chamber. The water jacket is thermally coupled to the outer conductive layer of the combustion chamber wall such that the water cools the outer conductive layer of the combustion chamber wall. Similarly, the water jacket may act as at least a portion of a thermal load that is heated by the combustion reaction.
In one embodiment, a conductor is positioned adjacent a bottom portion of the combustion chamber. Therefore, in one embodiment the process 500 includes applying a voltage to the conductor near the bottom of the combustion chamber. In this case, the conductor near the bottom of the combustion chamber acts as a counter electrode to the charger. The conductor at the bottom of the combustion chamber can be connected to ground or can carry any other suitable voltage to influence the combustion reaction. Alternatively, the conductor at the bottom of the combustion chamber can be connected to a voltage through an electrically resistive material.
In one embodiment the combustor burns liquid or gaseous fuel. In this case the conductor near the bottom of the electrode can be a conductive fuel nozzle from which fuel is output into the combustion chamber. Alternatively, if the combustor burns a solid fuel, the conductor near the bottom of the combustion chamber can be a conductive grid or mesh on which the solid fuel is disposed during combustion and/or during preheating awaiting combustion.
While the steps of the process 500 have been described as occurring in a particular order, the steps of the process 500 can be performed in different orders then shown in
While various aspects and embodiments have been disclosed herein, other aspects and embodiments are contemplated. 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.
The present application is a U.S. Continuation application which claims priority benefit under 35 U.S.C. §120 (pre-AIA) of co-pending International Patent Application No. PCT/US2014/058853, entitled “ELECTRICAL AND THERMAL INSULATION FOR A COMBUSTION SYSTEM,” filed Oct. 2, 2014 (docket number 2651-192-04); which application claims priority benefit from U.S. Provisional Patent Application No. 61/885,809, entitled “ELECTRICAL AND THERMAL INSULATION FOR A COMBUSTION SYSTEM,” filed Oct. 2, 2013 (docket number 2651-192-02), co-pending at the date of filing; each of which, to the extent not inconsistent with the disclosure herein, is incorporated herein by reference.
Number | Date | Country | |
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61885809 | Oct 2013 | US |
Number | Date | Country | |
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Parent | PCT/US2014/058853 | Oct 2014 | US |
Child | 15090241 | US |