The present disclosure is directed generally to dynamic sensors for detecting and/or measuring events in combustion engines, thermochemical regeneration process apparatuses, heat pipe apparatus, and the like and providing adaptive control.
Sensors and transducers are generally used to sense and/or measure external stimuli such as light, heat, sound, etc. Sensors and transducers are integrated in electrical devices for automation and control. For example, the carbon monoxide detector is a type of a transducer that is battery powered and detects carbon monoxide levels. When the carbon monoxide level is above a threshold, the detector sounds an alarm using a built-in speaker.
The present disclosure describes a dynamic sensor, and methods, systems and associated components for detecting and/or measuring various events, conditions, properties and/or presence of target samples using the dynamic sensor. In certain embodiments, the dynamic sensor provides a “tattletale” or other type of feedback indication related to events and conditions associated with operation of various systems and/or properties, conditions, presence, and/or other characteristics of a target sample. In other embodiments, the dynamic sensor can control the sensed or other events and conditions based on the detected or measured events and conditions.
According to aspects of the disclosure, the dynamic sensor can include both passive and active functionality. In one aspect, a dynamic sensor receives and registers input events and harvests energy from the input events to do additional work. For example, the dynamic sensor can convert energy from pressure, radiation, vibration, thermal gradients, etc. to electrical energy that can be stored in capacitors and used to power the components of the dynamic sensor. In a further aspect, the dynamic sensor emits a tracer signal (e.g., light, acoustic wave, etc.) or an interrogation signal to establish a base line for sensing by other sensors. The dynamic sensor can be a part of an acoustic modifier device and can be remotely triggered to emit acoustic waves for shaping a working fluid, such as air, fuel, plasma, etc. The emitted acoustic waves can also trigger supercavitation or phase shift in fluids to, for example, stimulate fluid movement.
According to aspects of the disclosure, the dynamic sensor or a collection of dynamic sensor nodes (i.e., dynamic sensor network) can communicate with each other using radio frequency or other wireless and/or wired communication methods. The dynamic sensor can provide real-time data collection, correction, and/or reporting. The dynamic sensor can also use radio frequency or other wireless and wired communication methods to report signals to a controller for actuating components of the system (e.g., actuating an igniter/injector), a central command that can evaluate reporting from various dynamic sensor nodes in the network as a whole to take certain actions.
The dynamic sensor can be integrated with combustion engines, thermochemical regeneration process apparatuses, heat pipe apparatus, and the like for sensing and adaptively controlling various events, operations and/or conditions in such systems. For example, the dynamic sensor can sense and control the ionization within a combustion chamber, associated systems, assemblies, components, and methods. Furthermore, several of the embodiments described below are directed to adaptively controlling the ionization within a combustion chamber based on various conditions within the combustion chamber and/or based on various conditions at regions at or near an igniter/injector within the combustion chamber. Multiple dynamic sensors can be placed in certain locations to determine, for example, shape and penetration rate of a plasma injection, control timing of injection, and the like.
Certain details are set forth in the following description and in Figures to provide a thorough understanding of various embodiments of the disclosure. However, other details describing well-known structures and systems often associated with internal combustion engines, injectors, igniters, and/or other aspects of combustion systems are not set forth below to avoid unnecessarily obscuring the description of various embodiments of the disclosure. Thus, it will be appreciated that several of the details set forth below are provided to describe the following embodiments in a manner sufficient to enable a person skilled in the relevant art to make and use the disclosed embodiments. Several of the details and advantages described below, however, may not be necessary to practice certain embodiments of the disclosure.
Many of the details, dimensions, angles; shapes, and other features shown in the Figures are merely illustrative of particular embodiments of the disclosure. Accordingly, other embodiments can have other details, dimensions, angles, and features without departing from the spirit or scope of the present disclosure. In addition, those of ordinary skill in the art will appreciate that further embodiments of the disclosure can be practiced without several of the details described below.
Reference throughout this specification to “one embodiment” or “an embodiment” means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the present disclosure. Thus, the occurrences of the phrases “in one embodiment” or “in an embodiment” in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments. The headings provided herein are for convenience only and do not interpret the scope or meaning of the claimed disclosure.
The input transducer unit 110 includes a sensing element, or an array of sensing elements and associated circuitry. The input transducer unit 110 may detect acoustic (e.g., wave, spectrum, wave velocity, etc.), electrical (charge, current, voltage, electric field, conductivity, resistivity, etc.), magnetic (e.g., magnetic field, magnetic flux, etc.), electromagnetic (e.g., light), optical (e.g., wave, wave velocity, refractive index, reflectivity, absorption, etc.), thermal (e.g. temperature, specific heat, thermal conductivity, etc.), mechanical (e.g., position, velocity, acceleration, force, stress, pressure, strain, mass, density, compliance, structure, orientation, vibration, etc.), chemical energy, and/or the like. In one embodiment, the dynamic sensor 100 may include multiple input transducer units 110. For example, one transducer unit may be used to detect and/or measure temperature, while another transducer unit may be used to detect and/or measure pressure. The multiple transducer units can be operational at the same time, or can be selectively turned on or off based on internal logic or external control signal 145.
The transceiver unit 130 includes receiver/transmitter (e.g., nano radio) for receiving and/or transmitting radio frequency signals between the components of the dynamic sensor 100, and between the dynamic sensor 100 and one or more components, including other dynamic sensor nodes external to the dynamic sensor 100. The transceiver unit 130, in one embodiment, may also receive a control signal 145 from other dynamic sensor nodes or controllers. The control signal 145 may be used to control various aspects of the operation of the dynamic sensor 100. For example, the control signal can be used to program the controller unit, provide a new baseline, reference, or other threshold parameter for storage in the memory unit 125, request reports on measured data, selectively turn on or off transducer units, turn on or off the dynamic sensor unit, and the like.
The controller or logic unit 120 processes one or more signals sensed or detected by the transducer unit 110 to determine and/or generate an output signal which is then transmitted to a component external to the dynamic sensor 100 using the transceiver unit 130. For example, the controller or logic unit 120 may compare detected signals from the transducer unit 110 with a base line signal, and determine whether or not to report the detected signals.
The memory unit 125 stores data relating to the detected signals, calibration data, and the like. The memory unit 125 is in communication with the input transducer unit 110, the controller or logic unit 120.
The energy collector or distributor 115 generates or harvests electrical energy from input energy 140, such as heat, light, vibration, acoustic and other energy in the environment, and uses the electrical energy to power one or more of the input transducer unit 110, the controller or logic unit 120, the memory unit 125 and the transceiver unit 130. The energy collector 115 may harvest energy from heat, light, acoustic and/or pressure generated from combustion, temperature difference from heat pipe apparatus, chemical reaction, vibration and the like. The energy collector or distributor 115 can be a photovoltaic system, a piezoelectric system, thermal gradient system, and the like. The energy collector or distributor 115 can also include an energy storage component such as a capacitor, charge collector, or a battery unit that can accumulate and store the energy for distribution when required.
At block 315, the dynamic sensor can produce electrical energy from radiation (photoelectric), pressure (piezoelectric), and/or heat (thermoelectric) generated during combustion events. At block 320, a portion of the electrical energy is utilized to report the sensed or detected combustion chamber conditions. At block 325, the reported signal can be utilized to adaptively control combustion chamber mechanics to adjust combustion chamber conditions. For example, the reported signal can be used to vary the time of beginning fuel injection to a combustion chamber, time of plasma, time of end of fuel injection, time between fuel injections, magnitude of ultrasonic impetus, fuel injection pressure, etc.
When the tube experiences an external pressure than exceeds the pressure inside the tube, the walls of the tube can collapse or deform. Using the Poisson effect, and material properties such as modulus of elasticity of the tube fiber, the strain on the tube wall can be determined, and correlated to the pressure acting on the tube wall. Alternately, the deformed or collapsed wall can produce a change in the interference pattern detected by the detector array 410. From the changed interference pattern, the change in pressure (from ambient pressure), or the actual pressure can be determined.
The same transducer 400 can be used to measure temperature. The effects of factors such as pressure may need to be decoupled to determine the temperature more accurately. For example, depending on the coefficient of expansion of the fiber, the tube walls can absorb energy and expand, thereby changing the interference pattern detected at the detector array 410.
In one embodiment, the source or emitter 415 may be one or more light emitting diodes (LEDs). The LEDs may be powered by the energy harvested from events in a combustion chamber, for example. In an alternate embodiment, the source or emitter 415 may be radiation from the combustion chamber. The radiation from the combustion chamber may include different wavelengths of light (e.g., Infrared, visible spectrum, etc.). The spatial resolution of the detector array may depend on the wavelength of radiation from the combustion chamber or the wavelength of the LED light that act as the source/emitter 415.
In one embodiment, the dynamic sensor can be used for monitoring and/or detecting one or more properties of a sample of a target material. For example, the dynamic sensor can be used for collecting a sufficient amount of a target sample, detecting the presence of the portion of the target sample and/or analyzing properties of the target sample, reporting an indication of the detection and/or analysis, and optionally clearing the target sample to enable repeated or cyclic collection of additional samples. Based on one or more factors related to the presence of the target sample or the properties of the target sample, the dynamic sensor can provide an indication of a suitable action or process in response to the detection and/or analysis. A networked array of such dynamic sensors can be used in various suitable environments including, for example, environments directed to quality assurance, preventative maintenance, safety (including trend analysis), hazard warnings (including shut down procedures), chemical identification and surveillance, environmental monitoring, and/or homeland security. The monitoring and/or detecting of one or more properties of a sample of a target material is described in detail in U.S. patent application Ser. No. 13/027,188, filed Feb. 14, 2011, now U.S. Pat. No. 8,312,759, issued Nov. 20, 2012, and entitled “METHODS, DEVICES, AND SYSTEMS FOR DETECTING PROPERTIES OF TARGET SAMPLES” (Attorney Docket No. 69545.8801.US01), and incorporated herein by reference in its entirety.
The system 450 generates ions 490 from fuel and/or constituents of the oxidant in the combustion chamber. Thus ions 490 may be generated from oxygen, nitrogen, water vapor, hydrogen, ammonia, methane, propane, ethane, methanol, ethanol or more complex fuel constituents. The system 450 determines temperature and/or pressure by the ion life and distribution by measuring and characterizing the magnitude, duration and trend of ionic currents between the electrode components of a combined plasma generator and fuel injector 484 and/or the insert sensors 474, 476, 478, 496 and 480 in the thermal dam and power producing and/or cooling inserts 464, 466 and 468 of the combustion chamber such as the head components including intake valve 482, exhaust valve 486, piston 472, and cylinder wall insert 468 in the engine assembly.
In some embodiments additional information including the radiation emissions from such ions and surrounding particles and surfaces are monitored by dynamic sensors having radiation and/or pressure transducers 492, 494, and/or 498 as shown including appropriate counterparts and components in other engines such as gas turbines, and various rotary engines.
In operation, ionizing voltage is delivered to electrodes 460 and 462 through insulated terminal 452 and/or such ionizing events may be powered by suitable high voltage generator such as piezoelectric components 488 within assembly 484 by conversion of pressure energy from the combustion chamber or from a mechanical device such as a cam to produce required strain. In some embodiments, sufficient ionization and/or maintenance of ion populations is aided by the voltage gradient between electrodes 462 or 460 and desired zones of inserts 464, 466, 468, and/or 470 as shown. Information from the dynamic sensors are sent to microprocessor 458 and/or to a computer that is external to assembly 484 for purposes of adaptive operation and control of fuel injection and ignition events. Signals from the dynamic sensors may be reported by suitable wireless frequencies, optical couplings, or by wired connections including various suitable combinations.
In various embodiments, information reported by dynamic sensors can be used for adaptive control. For instance, the reported information can be used to control the operation of the valves (e.g., 482, 486) (i.e., linear engine capability), operation of a tip magnet (not shown) to adjust plasma flow pattern, monitoring of ion flow (e.g., in response to speed of valve opening), monitoring the beginning, duration and end of combustion, and products of combustion, monitoring various conditions to optimize overall engine efficiency, and the like.
At block 440, the dynamic sensor can extract parameters from the interference pattern, such as distance between peaks or intensities, and the like. At block 442, the extracted parameters are correlated with pre-calibrated values of pressure to determine pressure on the transducer walls. A signal corresponding to the determined pressure value, or an alert is reported via radio frequency communication to a central controller at block 444.
During the compression portion or compression stroke of the cycle, the valves 510a and 510b are closed and the piston 508 moves in the direction of arrow 534. As the piston 508 moves towards a top dead center, the piston 508 decreases the volume of the combustion chamber 506 and accordingly increases the pressure within the combustion chamber 506. In certain embodiments, during the compression stroke, the injector 502 can dispense fuel F into the combustion chamber 506. For example, during predetermined operating conditions, such as for production of maximum fuel economy, particularly in conjunction with low load or low torque requirements, the injector 502 can dispense the fuel F during the compression stroke of the piston 508. Moreover, the injector 502 can dispense the fuel F in any desired distribution pattern, shape, stratified layers, etc. As such, during the compression stroke the piston 508 can compress the air-fuel mixture as the piston 508 reduces the volume of the chamber 506. In other embodiments, however, the system 500 can operate such that the injector 502 does not introduce fuel F into the combustion chamber 506 during the compression stroke of the piston 508.
One or more dynamic sensors such as 512, 514 are positioned inside or outside the combustion chamber, or on or near the injector, or at any other suitable locations such as those described with respect to
Referring to
As the piston moves in the direction of 534, each successive wave travels a shorter distance to reach the surface of the piston 508 from where it is reflected and the reflected waves 514a are detected by a detector 514 near the source 512. The change in the wavelength or frequency between the waves from the emitter 512 and the detector 514 can be determined by the dynamic sensor, and reported to a central controller or another entity as the velocity of the piston. From velocity, position, and acceleration of the piston can also be determined. The reporting of the information may be, for example, RF controlled, acoustic controlled and/or piezoelectrically controlled.
The acoustic waves that are reflected from the surface of the moving piston are detected by an acoustic transducer or detector array at block 554. The dynamic sensor can then determine the change in frequency between the acoustic wave that was emitted and the acoustic wave that was detected at block 556. The change in frequency can then be correlated with piston velocity at block 558. The correlation may be based on calibration data or other reference that can be stored in the memory of the dynamic sensor, for example. The determined piston velocity may be reported to a center controller or other dynamic sensor nodes at block 560. Alternately, the determined piston velocity may also be compared with a threshold range, for example, and when the piston velocity is outside of the range, an alert signal may be transmitted using RF communication to other nodes, a central controller, or directly to a component that controls the speed of the piston.
Dynamic Sensors with Radio Frequency (RF) Control
Radio interference and circuit component damages can occur due to solar flares or various anthropological mishaps or purposes including potential terrorism. Most of the existing transportation system and countless distributed energy applications could be disabled by electromagnetic radiation such as may be caused by a nuclear detonation and ionization of the atmosphere and other radio frequency radiation including solar flares of magnitudes. This is because of the transition to modern electronic control systems which use natural gas, liquid petroleum gases, diesel, and gasoline fueled engines, and can be susceptible to radio frequency damage.
Embodiments that utilize a microcontroller and a suitable actuator such as piezoelectric or a solenoid type driver assembly of coil and an armature may utilize the magnetic circuit provided within a radio frequency (RF) shielding enclosure. Such RF shielding enclosure can prevent externally sourced electromagnetic and other damaging radiation from harming electronics including semiconductor instrumentation and control components incorporated as circuit components of integrated Spark Injector or Smart Plug systems in one implementation. In a further implementation, the RF shielding enclosure can prevent unwanted cross communication between the Spark Injector or Smart Plug systems due to RF interference. In a further implementation, the RF shielding enclosure can prevent RF signals from Spark Injector or Smart Plug system components from causing interference to radios, televisions, and other appliances that are susceptible to such RF interference.
As illustrated in
Although it is illustrated near conductive tube 628, the location of relay 656 could be at other locations such as proximate to the inside of case 608 and winding 604 or a battery or capacitor 612. Secondary 604 is connected by conductive cable 660 to conductive tube or plating 628 and to relay 656 as shown. In operation relay 656 is closed to provide current through winding 604 and conductor 660 of cable 650 to ground connection 658 on case 603 until desired generation of spark or plasma generation between electrodes 628 and 634 at the interface with valve 640 as shown. When relay 656 opens the low impedance current path to ground, the voltage builds to generate the desired spark of plasma discharge in the gap at electrode 628, 638 to electrode 634 as shown. Similarly, the winding for solenoid operations may have three windings that operate as a solenoid coil until one winding is connected in series with another to serve as a secondary circuit and is electrically separated from the remaining winding which serves as the primary. Similarly, the winding for solenoid operations may have four or more windings that operate as a solenoid coil until one winding is used as the primary and the remaining windings are electrically separated and connected in series to form the secondary for spark voltage generation.
In applications such as engines with extended-life duty cycles, plasma voltage generated by one Spark Injector may be applied to one or more other Spark Injectors through cable such as 607 to provide a redundant source for assured spark generation. As depicted in
Effective development of the full potential of multiple layers of insulator material with high dielectric strength depends upon prevention or removal of impurities such as air, water, fingerprints, dust, etc., that typically deposit oligomers and various salts. Illustratively a spiral wound polyimide without such impurities can provide more than 7,000 Volts per layer or winding of film that is 0.001″ thick. Further improvement of dielectric containment of voltage may be provided by incorporation of anisotropic ion migration barrier particles or thin films on the base film such as polyimide polymer. Thus 60,000 volts can be delivered by the secondary with only six to eight turns of wrapped or coaxial layers of such composited impurity-free insulation. In production such insulation may be applied in one or more applications by physical or chemical vapor deposition, compression molding, injection molding, extrusion, calendaring, varnishing, or casting and separate layers may be incorporated with dissimilar materials including various ceramics and glass-ceramics as particles or films including depositions that provide oriented crystallization.
Micro and nano crystals along with deposited layers selected to provide charge migration barriers include alumina, magnesia, quartz, mica, various titanates such as barium titanate, ZnO and such crystal selections may be encapsulated in condensation polymers such as thin piezoelectric polyvinylidene fluoride films. Similarly full or partial encapsulation may be by non-piezoelectric polyolefin, or poly (p-xylene) films. Procedures for impurity free developments of the required insulation values are similar to those employed for semiconductor manufacturing and include production in clean room or clean chamber equipment. Thus the steps include production and maintenance of high purity materials and feed stocks such as semiconductor grade, constant prevention of contaminants from being admitted to the production stage, and completion of the insulation system by drying to remove moisture or elevating the temperature sufficiently to remove moisture and removing air by suitably pressing or vacuum sealing the resulting component(s) against invasion by contaminants. This requires purity assurance instrumentation to detect and prevent virtually every aspect of contamination.
Thin layers 650 of polymer, ceramic or glass-ceramics with nano-sized crystal precipitates or deposits 654 that are oriented parallel to conductor 660 as shown in
In applications where it is desirable to utilize a more rapid operator to control valves such as 638, including instances of various combinations with a fuel distributor, armature 614 may be provided with or as a piezoelectric component in a suitably connected electrical circuit with one or more inductive windings such as 604 and 662. This provides efficient close coupling of the transformer and/or capacitor 612 to the piezoelectric driver and provides prevention of RF transmission to or from the integrated Spark Injector or Smart Plug.
Rapid cycling of the fuel control valve is facilitated as may be desired by high-speed action of the piezoelectric driver and spark or plasma generation is provided by the circuit controlled by relay 656 to adaptively optimize fuel efficiency and prevention of emissions including oxides of nitrogen, carbon monoxide, and hydrocarbons. In some applications it is desirable to utilize the inductive energy from another Spark Injector system as may be delivered by cable such as 607 to provide one or more spark or plasma discharges and/or to provide one or more piezoelectric valve drive operations. In instances that armature 614 is provided as a combination of an electromagnetic and piezoelectric driver, various modes of operation are enabled including longer motion by the electromagnetic element and shorter and potentially faster motions by the piezoelectric element to produce commensurately proportioned and conditioned fuel flow timing and rates from the fuel control valve such as 638 that is chosen for various optimized applications. This provides new optimization parameters for controlling fuel penetration into air in the combustion chamber including control of surface to volume characteristics, air insulation pattern, combustion rates, combustion pattern, combustion characterization, and air utilization efficiency.
In illustrative combined fuel-injection and spark-ignition operation in application on a heat engine, a relatively small amount of the thermal and pressure energy produced in the combustion chamber of the engine may be converted by one or more generators such as piezoelectric, photo voltaic, and or thermoelectric devices and delivered for storage in a battery, reversible fuel cell, or capacitor 612. Such stored energy may power micro-computer 606 and armature 614 which may be an appropriate actuator component of an electromagnetic, piezoelectric, pneumatic, hydraulic, combined pneumatic and hydraulic, or combined electromagnetic and piezoelectric circuit. Control including adaptive response to operation requirements and data derived by sensing of pressure, temperature, and dynamic combustion characteristics of the heat engine along with conditioning and switching of electric current at appropriate voltage for such purposes may be provided by a circuit including appropriate relays and an effective transformer, solenoid, or combined solenoid and transformer such as 662 and 604.
Utilization of direct conversion generators including piezoelectric, photovoltaic, and or thermoelectric devices to harvest a relatively minute amount of ordinarily wasted energy that is released in the engine's combustion chamber greatly improves the overall energy conversion efficiency of vehicular and distributed power applications compared to requiring the engine to produce shaft power that is mechanically conveyed to an alternator that electrically conveys energy to a battery that supplies electricity for Spark Injector operations. This is because generation and delivery of energy from the engine's output shaft, at best, incurs a loss of 50% or more from the energy available in the combustion chamber which is diminished by further losses to drive and operate an alternator that incurs losses that may vary from about 20 to 80% depending upon the engine speed and condition of the lead-acid storage battery and is further diminished by various circuit losses required to deliver energy needed for fuel-injection and spark-ignition operations.
The resulting Spark Injector or Smart Plug embodiment including versions that provide energy conversion operations is less expensive to produce, more efficient in operation, and more reliable as a comprehensive integrated system than conventional systems that have separately packaged components such as a distributor, coil, spark plug, and fuel injector. In operation the comprehensive system is able to withstand RF magnitudes that disable conventional electronically controlled fuel injection and ignition systems. Preventing and or containing RF radiation within the integrated package enables much more efficient low resistance conveyance of plasma or spark energy from the transformer coil to the ignition gap because it is not necessary to utilize conventional high resistance spark plug cable of considerably longer length. Energy is delivered to the spark or plasma that is ordinarily dissipated due to impedance losses to minimize radio frequency radiation that would escape from low resistance spark plug cable.
In applications such as 100 mpg family cars, 200 mpg sub-compact vehicles, and 600 mpg motorcycles Spark Injectors enable far more efficient engine operation to provide propulsion with much greater overall fuel efficiency than conventional combinations that include an engine along with an alternator and battery as separate devices. This facilitates a much more efficient conversion of kinetic energy as a vehicle is slowed or stopped by a driveline generator that delivers energy to the reversible electrolyzer disclosed in U.S. patent application Ser. No. 12/707,651, filed Feb. 17, 2010 (now U.S. Pat. No. 8,075,748, issued Dec. 13, 2011) and entitled “ELECTROLYTIC CELL AND METHOD OF USE THEREOF” (Attorney Docket No. 69545-8101.US01), which is incorporated herein by reference in its entirety.
In heavy trucks and rail locomotive applications conversion of much larger kinetic energy as trains are slowed or stopped by delivery of electricity from the reversible electric drive motors to such electrolyzers. RF damages to electrical equipment due to previous solar flares consequences are sudden, expensive, and may be disabling or debilitating for months. Future damages to transformers and other components of the electric transmission grid and essential appliances including life-support appliances can be prevented by using improved voltage-containment, insulation, multi-functional systems, and RF control systems and technologies disclosed herein. The same principles and embodiments disclosed herein for Spark Injector or Smart Plug applications provide improvements and safeguards for a very wide variety of electrical, electronic, electromechanical, computer, and instrumentation components and systems.
Hydrogen characterized combustion is seven to ten times faster than hydrocarbons such as methane and therefore enables much more torque to be developed per calorie or BTU of heat released than slower burning fuels that require much earlier ignition and thus cause heat loss and counter-torque losses during the compression period of engine operation.
Equation 701 summarizes the general process for hydrocarbons such as diesel fuel, gasoline, natural gas, propane, ethane, etc.:
HxCy+yH2O+HEAT1→yCO+(y+0.5x)H2 Equation 701
CH4+H2O+HEAT→CO+3H2 Equation 702
Equation 702 summarizes the production of oxygenated carbon fuel as shown whereby methane is reacted with steam to produce carbon monoxide and hydrogen.
In addition to production of oxygenated fuel species from hydrocarbons, another embodiment produces oxygenated fuel species from low cost fuels such as mixtures of alcohol, water and a carbon donor. Equation 703 summarizes the process for an alcohol such as butanol and a carbon donor, for example, a colloidal or otherwise suspended substance containing carbon, such as a cellulose, sugar, starch, fat or protein from a waste source.
C4H9OH+4H2O+C+HEAT3→5CO+9H2 Equation 702
Referring to
Alternative configurations, as one skilled in the art would understand, are within the scope of the disclosure. Hot steam from the exhaust stream passes across membrane 708 for supplying or supplementing other sources of water utilized in Equation 701. According to further aspects of the disclosure, regenerative energy as may be provided by energy harvesting operations such as regenerative braking or harvesting of combustion chamber energy sources including vibration, radiation, and pressure may be delivered to the tubular heat exchanger 704 by a suitable inductive or resistance heater 752 by connections 775, 777 as shown.
Considerable thermal banking or retention of such heat in surplus of the amount consumed by the endothermic process of Equations 701, 702 or 703 may be provided by material selections such as graphite or boron nitride. Alternatively or additionally, a change of phase heat exchanger and storage capability may be provided by substances such as salt compositions that change phase at a desired temperature such as at or above the temperature required for processes such as shown in Equations 701, 702 and 703. Such thermal banking materials and/or phase change storage may be provided in the those shown in Equations 700, 702, and 703 are thus heated to adequate temperature for the reactions indicated and delivered to reaction zone 708 and 706 by insulated tubing 762 as shown.
The stream of hot fuel constituents such as hydrogen and carbon monoxide produced by reactions shown in Equations 701, 702 and 703, is cooled by counter current heat exchange with fuel from the tank 738. An optimization controller 755 controls fuel delivery through control valves 744 and 754. Accordingly, in operation, the fuel from tank 738 is heated to approximately the temperature of the products from the reactor 706, while the stream of hydrogen and carbon monoxide is cooled to nearly the temperature of fuel from tank 738.
This thermochemical regeneration system provides hydrogen-characterized fuel with superior heat removal capabilities for circulation within desired spaces and places for cooling one or more fuel injection valves 766, which in turn control direct fuel injection into the combustion chambers of the engine 732. A resistance or inductive heater 770 with connections 768, 772 may be utilized to further apply heat which has been generated from energy harvesting operations to increase the temperature of fuel delivered by insulated tubing 760 to reaction zone 706. The thermochemical regeneration processes are described in further detail in U.S. patent application Ser. No. 12/804,509, filed Jul. 21, 2010 and entitled “METHOD AND SYSTEM OF THERMOCHEMICAL REGENERATION TO PROVIDE OXYGENATED FUEL FOR EXAMPLE, WITH FUEL-COOLED INJECTORS” (Attorney Docket No. 69545-8310), which is incorporated herein by reference in its entirety.
In one embodiment, the dynamic sensor used in the thermochemical regeneration system illustrated in
CH4+H2O+HEAT→CO+2H2+CH4+H2O Equation 702
In one implementation, the dynamic sensor can include a tunable laser that produces a light beam having a wavelength that corresponds to the absorption band of a chemical species for illuminating a combustion chamber. When a targeted chemical species is present in the combustion chamber, the molecules of the target chemical species absorb some of the energy and an attenuated laser beam (or reflected and attenuated laser beam) hits a detector in the dynamic sensor. Alternately, the process described in U.S. Pat. No. 7,075,653 and/or the references cited in the patent may be used for detecting a chemical species using the dynamic sensor. The dynamic sensor capable of detecting chemical specifies can be attached to one or more fiber optic connected and/or integrated monitors in the Spark Injector to detect a chemical species such as methane. Detection of methane, for example, allows for adaptive optimization of the thermochemical regeneration process, injection pressure, ionization timing, turbocharger management, and the like. In some instances, the status of the thermochemical regeneration process may be monitored along with other injection and combustion processes to ensure emission free operations. In some instances, in addition to methane detection, a number of other constituents such as ozone (O3), radicals such as methyl (CH3), methylene (CH2), carbyne (CH), nitrous oxide (N2O), nitrogen monoxide (NO), nitrogen dioxide (NO2), along with the occurrence of any carbon-rich particles can be detected by the dynamic sensor by tuning the light or laser beam to a particular wavelength.
In some embodiments, designer fuels that may include one or more fuel additives or chemical tracers (e.g., gas crystal) that emit radiation having a wave length or a wave length pattern that is specific to combustion chamber conditions such as temperature, pressure, products of combustion, and the like may be used. The dynamic sensor can then detect the emitted wave length or pattern triggered by an event in the combustion chamber.
One or more dynamic sensors located in the reaction zone or proximate to the reaction zone of the TCR apparatus can monitor conditions such as temperature and/or pressure in the reaction zone at block 802. In one implementation, dynamic sensors for detecting and/or monitoring constituents of fuel such as hydrogen, carbon monoxide, and/or a feed stock such as propane, ammonia, urea, or methane may also be located in the reaction zone or proximate to the reaction zone. At block 804, constituents of fuel and/or conditions in the combustion chamber of a combustion engine may be detected and/or monitored. Alternately, signals corresponding to the detected constituent of the fuel and/or detected conditions in the combustion chamber may be received. At decision block 806, if the combustion efficiency within a desired or predefined range, the conditions in the reaction zone may be maintained at block 808. For example, the heat supply to the reaction zone may be maintained. Alternately, if the combustion efficiency is outside of the range, one or more parameters may be adjusted at block 810 to bring the efficiency of the combustion process within a desired range. The combustion efficiency may be determined or gauged from various information such as the methane level, temperature, pressure, acoustic signature, and the like in the combustion chamber.
The following examples are illustrative of several embodiments of the disclosed dynamic sensors.
Unless the context clearly requires otherwise, throughout the description and the claims, the words “comprise,” “comprising,” and the like are to be construed in an inclusive sense as opposed to an exclusive or exhaustive sense; that is to say, in a sense of “including, but not limited to.” Words using the singular or plural number also include the plural or singular number, respectively. When the claims use the word “or” in reference to a list of two or more items, that word covers all of the following interpretations of the word: any of the items in the list, all of the items in the list, and any combination of the items in the list.
From the foregoing, it will be appreciated that specific embodiments of the invention have been described herein for purposes of illustration, but that various modifications may be made without deviating from the spirit and scope of the invention. Accordingly, the invention is not limited except as by the appended claims.
The present application claims priority to and benefit of U.S. Patent Application No. 61/682,681 titled “DYNAMIC SENSOR” filed on Aug. 13, 2012, which is incorporated by reference herein. The present application is related to U.S. patent application Ser. No. 13/027,188, filed Feb. 14, 2011 (now U.S. Pat. No. 8,312,759, issued Nov. 20, 2012) and entitled “METHODS, DEVICES, AND SYSTEMS FOR DETECTING PROPERTIES OF TARGET SAMPLES” (Attorney Docket No. 69545.8801.US01); U.S. patent application Ser. No. 12/653,085, filed Dec. 7, 2009 and entitled “INTEGRATED FUEL “INTEGRATED FUEL INJECTORS AND IGNITERS AND ASSOCIATED METHODS OF USE AND MANUFACTURE” (Attorney Docket No. 69545-8304.US00); U.S. patent application Ser. No. 12/841,170, filed Jul. 21, 2010 and entitled “INTEGRATED FUEL INJECTORS AND IGNITERS AND ASSOCIATED METHODS OF USE AND MANUFACTURE” (Attorney Docket No. 69545-8305.US00); U.S. patent application Ser. No. 12/804,509, filed Jul. 21, 2010 and entitled “METHOD AND SYSTEM OF THERMOCHEMICAL REGENERATION TO PROVIDE OXYGENATED FUEL FOR EXAMPLE, WITH FUEL-COOLED INJECTORS” (Attorney Docket No. 69545-8310.US00); and U.S. patent application Ser. No. 12/707,651, filed Feb. 17, 2010 (now U.S. Pat. No. 8,075,748, issued Dec. 13, 2011) and entitled “ELECTROLYTIC CELL AND METHOD OF USE THEREOF” (Attorney Docket No. 69545-8101.US01). The aforementioned applications are incorporated herein by reference in their entirety.
Number | Date | Country | |
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61682681 | Aug 2012 | US |