Patent Document

CROSS-REFERENCE TO RELATED APPLICATION 
     This is a divisional application of Ser. No. 11/507,691, filed Aug. 22, 2006, and entitled ACOUSTIC ACCELERATION OF FLUID MIXING IN POROUS MATERIALS, and now abandoned, the disclosure of which is incorporated by reference herein in its entirety as if set forth at length. 
    
    
     BACKGROUND OF THE INVENTION 
     The invention relates generally to the field of combining fluids. More specifically, the invention relates to apparatus and methods for uniformly mixing fluid phases entrained in a porous medium. 
     The mixing of fluids is frequently needed to perform chemical reactions. Most chemical reactions require a controlled and homogeneous mixing of reagents. 
     A conventional means of mixing two or more miscible liquids is mechanical manipulation to stir and exploit fluidic forces to produce localized regions corresponding to relatively high fluid flow rates. The flow rates operate to produce localized turbulent forces within the fluid field. The turbulence provides a contact surface between the liquids such that diffusion of the fluid components into each other produces a homogeneous mixture. 
     Mixing also includes homogeneous compositions of immiscible fluids such as oil and air, typically used in oil jet pumps for gear lubrication. Oil and air are not miscible in a chemical sense, but may be combined in a mechanical sense. The term frequently used for mixing immiscible substances is homogenization. 
     Ultrasonic mixers use piezoelectric transducers to generate vibrations. High power output may be required to maintain the desired amplitude and intensity under conditions of increased load such as high viscosity or immiscibility. 
     When a porous medium, such as a polymer membrane, is used to contain reagents, equilibrium diffusion is problematic. While ultrasonic mixers have been employed to provide bulk mixing of liquid and gas, they have not been successfully employed for porous materials. Typically, the only known approach for mixing intensification inside porous bodies has been mechanical manipulation which might not be feasible or desirable in every case. 
     What is desired is a controlled acceleration of mixing in porous media. This would result in smaller physical component packaging for synthesizing units housing porous media such as those used for chemical reactors, fuel cells, and the like. 
     SUMMARY OF THE INVENTION 
     Although there are various types of mechanical manipulation mixing apparatus, such mixers are not completely satisfactory for porous media. The inventor has discovered that it would be desirable to have apparatus and methods for uniformly mixing fluid phases entrained in porous media. 
     One aspect of the invention provides a porous material mixer. Mixers according to this aspect of the invention comprise a vessel. At least one porous medium/material is held by the vessel. At least one actuator is acoustically coupled with at least one wall of the vessel for generating a wave. There is at least one inlet in the vessel for admitting at least two fluids for combining, wherein the wave effects mixing of the at least two fluids in the at least one porous material. 
     Another aspect of the invention is a method for mixing at least two fluids in a porous material. Methods according to this aspect begin with introducing the fluids into porous material held by a mixing vessel, the mixing vessel comprising at least one inlet, at least one linear motor coupled to at least one actuator wherein the actuator is acoustically coupled to a wall of the vessel, exciting the at least one linear motor with a control signal of predetermined frequency, and forming a compression/expansion wave determined by the actuator acoustic coupling and the predetermined frequency wherein fluid motion in the porous material within the vessel is effected. 
     The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention will be apparent from the description and drawings, and from the claims. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a perspective view of an exemplary ultrasonic porous media mixer with a top cover removed. 
         FIG. 2  is a plan view of the ultrasonic mixer of  FIG. 1  in a first position. 
         FIG. 3  is a plan view of the ultrasonic mixer of  FIG. 1  in a second position. 
         FIG. 4  is a plot showing an initial distribution of two immiscible fluids in the porous media. 
         FIG. 5  is a plot showing the direction of liquid A inside the porous media without any acoustic wave applied. 
         FIG. 6  is a plot showing the concentration of  FIG. 5  and direction of liquid A using the mixer according to the invention. 
         FIG. 7  is an exemplary alternative embodiment. 
     
    
    
     DETAILED DESCRIPTION 
     Embodiments of the invention will be described with reference to the accompanying drawing figures wherein like numbers represent like elements throughout. Further, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of “including,” “comprising,” or “having” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. The terms “mounted,” “connected,” and “coupled” are used broadly and encompass both direct and indirect mounting, connecting, and coupling. Further, “connected” and “coupled” are not restricted to physical or mechanical connections or couplings. 
     The invention is an apparatus and method for uniformly mixing together at least two fluids, or reagents, in viscous or gaseous phases, either miscible or immiscible, in a porous medium. The invention may be used for any application that requires uniformly mixing fluids. 
     Shown in  FIG. 1  is a mixer  101  for combining reagents introduced into a porous media  103 . The mixer  101  comprises at least one porous medium  103 , such as a porous ceramic used for oxidizing toxic waste, a fluidized bed with catalyst or palladium-coated metal membranes for generating hydrogen, a silica-alumina membrane for dehydrating isopropyl alcohol or synthesizing dimethyl carbonate from carbon dioxide and methanol, a symmetrical hydrophobic nylon 66 membrane for adsorbing enzymes, and other media, contained in a rigid vessel  105 . The vessel may be made from materials that transmit acoustic waves and are compatible with the fluids to be mixed, such as but not limited to stainless steel, ceramics, plastics and others. The exemplary embodiment is shown as a cubic volume, however, other vessel shapes and configurations may be used according to the mixer application and teachings of the invention. 
     The preferred embodiment has two inlets  107 ,  109  for admitting reagents A and B to mix together as they interact with the porous media  103 . Two outlets  108 ,  110  are provided and may be positioned perpendicular to the inlets  107 ,  109 . In the exemplary embodiment, the inlets  107 ,  109  and outlets  108 ,  110  are located on opposing sides of the vessel  105 . However, the inlets  107 ,  109  and outlets  108 ,  110  may be located on adjacent sides, or on the same side of the vessel  105 , or in any other suitable arrangement. 
     Located on opposite sides of the vessel are actuators  111 ,  113  that translate a linear motion from at least one linear motor, such as a piezoelectric transducer  115 ,  117  into a controlled compression/expansion wave to effect mixing in the porous media  103 . The piezoelectric transducer(s)  115 ,  117  may be, for example, interdigitated electroded actuators, oriented multilayer-multifilament stacked piezoelectric composites, piezoelectric wafer actuators, or others. In embodiments, the transducers  115 ,  117  produce a deformation, or linear excursion in a range of from about 1 to 20% of the porous layer width, which may be in a range from about 0.1 microns to 1.0 cm dependent on the technological task when excited by a variable magnitude control signal. The vessel internal volume may contain one mono-layer, a sandwich of more than one type of porous media, or may be completely filled with more than one type of porous media. When a control signal of fixed or variable frequency is impressed, the transducer may vibrate from audible to ultrasonic frequencies. The frequency range may be in a range of from about 10 kHz to 100 MHz. The piezoelectric transducers  115 ,  117  may be electrically coupled to a variable frequency oscillator for excitation (not shown). 
     Deformation of a piezoelectric transducer plate generally corresponds to a motion along the axis normal to the plate. For interdigitated electroded actuators, which are typically rectangular, the excursion is in the longitudinal direction. The embodiment shown in  FIG. 1  uses interdigitated electroded actuators. 
     Since the porous medium  103  is flexible in three dimensions, at least two sidewalls  119 ,  121  of the vessel  105  exhibit an acoustical impedance that allow for a controlled waveform to be impressed into the porous medium  103 . In the preferred embodiment, the transducers  115 ,  117  are coupled to a stationary support and to the actuators  111 ,  113 . A transducer  115 ,  117  excursion is transferred to a respective actuator  111 ,  113  which may be hinged in/by/at a hinge  118 ,  120  allowing for reciprocal movement about a hinge axis  122 ,  124 . 
     Shown in  FIG. 2  is a view of the mixer  101  with two transducers  115 ,  117  where a compression wave  203  is applied to one half of the porous media and a reciprocal expansion wave  201  to the other half of the porous media.  FIG. 3  shows the alternating nature of the applied force when the transducers  115 ,  117  are at a positive excursion. Each actuator  111 ,  113  alternately imparts a compression  203 /expansion  201  wave. Each transducer  115 ,  117  excitation is in unison with each other. 
     The actuators  111 ,  113  transfer the linear excursion from the transducers  115 ,  117  into a compression  203 /expansion  201  wave indirectly to the porous media  103  via the sidewalls  119 ,  121 . Each actuator employs at least two acoustic coupling points  205 ,  207 ,  209 ,  211  separated by a predefined distance corresponding to the actuator  111 ,  113 . The points  205 ,  207 ,  209 ,  211  provide and act as the point source of acoustical energy from the transducers  115 ,  117  to the porous media  103 . 
     Shown in  FIG. 4  is a plot of initial reactant location within the mixer  101 . The initial concentrations of reactants A and B are located at their respective inlet  107 ,  109  sides of the mixer. The plot shows gradual diffusion at the vessel  105  midpoint with no vibration. They slowly diffuse inwards toward the middle of the porous media. The reactant A slowly diffuses into the volume occupied by the reactant B and vise versa such that the concentrations of A and B reach equilibrium values about ½ way uniformly across the vessel. The dimensions of the mixer are as required to achieve the desired productivity. 
     The plot of  FIG. 5  shows gradual diffusion at the vessel  105  midpoint with no vibration. The fluids slowly diffuse inwards toward the middle of the porous media. The reactant A slowly diffuses into the volume occupied by the reactant B and vise versa such that the concentrations of A and B reach equilibrium values about ½ way uniformly across the vessel  105 . The dimensions of the mixer are as required to achieve the desired productivity. 
     Shown in  FIG. 6  is a plot showing the same reactant concentrations as in  FIG. 5 , with the compression/expansion wave applied by the invention  101  frozen in time. The transducers  115 ,  117  are excited using a frequency of 10 MHz. The plot shows enhanced mixing of the reactants when the compression/expansion wave is applied, with no additional mechanical manipulation. 
     The parameters of the porous medium  103  shown in  FIGS. 5 and 6  are those of Torrey paper. Torrey paper is a porous material used in fuel cell applications. Porosity is a non-dimensional quantity being the ratio of free space to the total volume of the material. The concentration change toward equilibration in the porous media  103  is calculated as 1.8*10 −7  per one period of vibration. The value indicates that during the time equal to one vibration period, the concentration in non-dimensional units (the ratio of the volume occupied by A or B to the total volume) has changed by 1.8*10 −7 . The value 0.00000018 is small, however, the period,
 
 V= 1/ t,   (1)
 
     where V is the frequency and t is the period, of a 10 MHz vibration is very short and substantial changes in concentration may be reached in the short time for frequencies of 10 MHz and higher. 
       FIG. 6  shows the concentration change toward equilibrium in the porous media  103  when using the mixer  101  as 0.4*10 −5  per one period of vibration. With this invention, mixing acceleration is approximately 22 times greater for a chosen porous media using a 10 MHz excitation having an amplitude equal to 0.1 of the sample width. In other words, by applying a 10 MHz vibration with an amplitude equal to 1/10 of the vessel thickness, the concentration change towards equilibrium is approximately 22 times faster than without the vibration (ratio of 0.4*10 −5  to 1.8*10 −7 ). 
     The acoustic perturbation of the porous material  103  using the compression/expansion wave of the invention accelerates the mixing of the reactants to more than 20 times that of natural diffusion. Multiphase flow in the porous medium  103  when subjected to the compression/expansion wave show dramatic enhancement of mixing compared to natural diffusion of the two reacting fluids inside the porous sample. 
     The exemplary embodiment shown in  FIG. 1  is one instance of the general approach to accelerating and controlling the mixing of at least two reactants inside at least one porous medium. Shown in  FIG. 7  is an alternate embodiment of the invention  701 . The alternative embodiment employs 4 pairs of transducer/actuators  705 ,  707 ,  709 ,  711 ,  713 ,  715 ,  717 ,  719 . 
     The wave imparted by the transducer/actuators  705 ,  707 ,  709 ,  711 ,  713 ,  715 ,  717 ,  719  exert force on two opposing surfaces of at least one porous medium  721  containing, at an initial stage, separate liquids A through I introduced through a micro-channel plenum (not shown). The motion of the invention is synchronized such that each transducer excursion is in unison. Transducer/actuators  705 ,  709 ,  713 ,  717  and  707 ,  711 ,  715 ,  719  may be a lower and an upper part of the same transducer assembly, respectively. This means that the transducers that exert force synchronously may be designed as one entity, as N/2, rather than requiring N separate transducers (one transducer for each actuator), such that one source of ultrasonic energy is divided and channeled to the required point sources of application by which synchronization is achieved. 
     Modifications to the acoustic perturbation wave shape applied to the porous medium and to the frequency may be used to optimize the rate of mixing in any porous medium structure geometry. Moreover, hybridization of the transducer syncing may further optimize mixing efficiency, where each pair of transducer/actuators  705 / 707 ,  709 / 711 ,  713 / 715 ,  717 / 719  may not be in complete synchronicity, or phase, with other pairs, but with each operating at a predetermined phase shift from other pairs. 
     In other representative and exemplary applications, various embodiments of the invention may be employed, for example, to mix methanol and water in a reformed hydrogen fuel cell and/or a direct methanol fuel cell. Additionally, various embodiments of the invention have demonstrated the capability to mix a variety of fluids including, for example, gases, liquids, gas-liquid mixtures, etc. Other representative applications may include the mixing of fuels supplying a micro-reactor and/or micro-combustion chamber. 
     One or more embodiments of the present invention have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the invention. Accordingly, other embodiments are within the scope of the following claims.

Technology Category: b