Abstract:
A method of generating an electric current by accurately dispensing a finite equal quantity of fluidized alkaline metals at equally spaced intervals into an injector water spray for subsequent reaction in live steam in a reaction chamber releasing electrons for an ionic capacitor of a capacitor tuyere.

Description:
CROSS REFERENCES 
       [0001]    The invention presented is preceded by the following U.S. Patents and co-pending U.S. Applications. 
         [0000]    Ref. 1 U.S. patent application Ser. No. 12/055,093 filed Dec. 26, 2007 Potassium Electric Generator and Chemical Synthesizer.
 
Ref. 2 U.S. Pat. No. 6,653,007 Hydrogen Generator.
 
Ref. 3 U.S. Pat. No. 7,288,335 Alkaline Electrode Tape.
 
Ref. 4 U.S. Pat. No. 6,831,825 Fuel Cell Ionic Capacitor.
 
Ref. 5 U.S. Pat. No. 7,381,378B2 Coal Flue Gas Scrubber
 
     
    
     BACKGROUND OF THE INVENTION 
       [0002]    An electrical current is generated at discrete intervals to produce intense individual pulses of direct current electron flow that is released during the cyclic hydrolysis of small quantities of fluidized alkaline metals, Li, Na, K, and with mixtures of alkaline earth metals, Ca and Mg, in a reaction chamber. The mechanism used for dispensing the said alkaline metals into the said reaction chamber producing individual segmented flowing quantities of the said fluidized alkaline metals at evenly spaced and controlled intervals is hereinafter termed a simplex generator. When the said simplex generator produces overlapping pulses, as those described in Ref. 1, it is termed a multiplex generator to be used principally for chemical synthesis. 
         [0003]    Simplex generators are best used in direct current electrical generation for transformer operation, a task most generally reserved for alternating current (ac) circuits. Simplex generators used in conjunction with an injector create large surging pulses of free electrons which produce strong magnetic field forces across the secondary windings of a transformer. Pulsing direct current transformers are more efficient than alternating current transformers because the current flow is only in one direction such that hysteresis losses are low because the transformer iron core magnetic field reversal does not occur and therefore does not inhibit the capacitor tuyere die-away factor continued current flow that is described in Ref. 1. 
         [0004]    Multiplex generator transformer operation is less effective than simplex generator transformer operation because the amplitude of the current pulse generated is lower. The said simplex generator system current slope is much more pronounced than the said multiplex generator compared at the same cycle rate. At the said higher slope amplitude the magnetic flux generated by the primary core winding must cut across the conductor of the secondary coil at a higher rate generating a higher current transfer. 
         [0005]    Multiplex generators are best suited for the rupture of carbon dioxide double bonds to produce calcium cyanamide or the formation of dicarboxyillic acids for use in organic synthesis. 
         [0006]    The said current flow that is generated by the simplex generator is the result of the shearing action of the bonds of the water molecule by reaction with an alkaline metal in a reaction chamber releasing the bonding electrons which hold the hydrogen atom to the oxygen atom. In the sodium hydrolysis one negative charged electron, and one positively charged proton, and a sodium hydroxyl ion are produced (Na+H 2 O→NaOH+H + +e − ). Because the reactions of the alkaline earth metals of Group II (Mg, Ca) are slower reacting during hydrolysis than the alkaline metals of Group I (Li, Na, K) mixtures of the two Groups are formulated as described in Ref. 2. 
         [0007]    The method of accurately dispensing small measured quantities of Group I and Group II metals for hydrolysis at equally spaced intervals in a cathode electrolyte proposed in Ref. 2 was to seal the reactants between two tapes. A pin roller was used to puncture the tape while it was submerged beneath the cathode electrolyte exposed the alkaline metal substances for hydrolysis. The design was improved in Ref. 3 Patent by the use of a perforated tape and a stripper tape to expose the metals for hydrolysis in the cathode electrolyte in later designs. Electrons released in the cathode electrolyte were then conducted to the anode electrolyte by an ionic capacitor described in Ref. 4 which in the current design is termed the capacitor tuyere of Ref. 1. 
         [0008]    In the present invention larger quantities of reactant alkaline metals are required for higher current loads. The said tape dispensing methods are replaced by a rotating shaft orifice which opens and closes the flow of fluidized mixtures of alkaline metals 60 times a minute (60 hz) releasing the metals for injection into a hydrolyzing reaction chamber. The reacted ionized stream is then released into the capacitor tuyere of Ref 1 where it is converted into a 60 hz pulsing direct current used for electrical direct current transformer operation. 
         [0009]    Machine screws and threaded bolt fasteners are simple design features common to most mechanical construction just as rectilinear reciprocating movement of pintle rods controlling the up and down motion of plug valves or threaded mechanism for raising and lowering of gate valves, or the rotation of spindle shaft petcock valving, are also established design features of flowing processes and are of themselves no longer qualified as novel. The novel feature of the present invention described is the integrated assembly of prefabricated machine process elements used for the cyclic alkaline metal valving process for the delivery of controlled quantities fluidized alkaline metals into an injector passing subsequently into a hydrolyzation reaction chamber to produce an uninterrupted series of electron pulses into a capacitor tuyere. The said capacitor tuyere receives and collects the 60 hz pulsing surge current for use in an electrical transformer primary winding induction circuit to produce an induced current flow in the secondary winding of said transformer. A novel feature of the invention is the spindle shaft petcock valving system shaft which is made to rotate in the same direction at 30 rpm opening and closing the flow to the injector at a cyclic rate of 60 hz. Operation in this manner controls the distribution of finite quantities of fluidized metal for the production of electron flow at 60 hz pulses. 
         [0010]    High pressure water introduced into the said injector and condensed live steam passing into the reaction chamber is collected at the said capacitor tuyere exit as a value added product to be subsequently used as an ejector liquid spray in Ref. 5 Coal Flue Gas Scrubber. The said tuyere water is rich in positive open bond material which increases retention of CO 2  during the scrubbing operation. The increased retention results from improved colligative properties of ejector spray water which strengthens the hydrogen to hydrogen bond between water molecules in the Capture matrix. 
         [0011]    There are three general methods used in the dissociation of the water molecule, electrolysis, thermal dissociation, and by chemical reaction with reduced alkaline metals. All three said methods are present in the simplex electrolytic flow circuits of the invention. Chemical reaction begins at the injector. After thermal dissociation the retention of ion charge passing into the capacitor tuyere is enhanced by live steam from boiler system fire wall cooling circuit which is passed into the reaction chamber and electrolytic dissociation continues and is maintained in the capacitor tuyere circuits. 
       SUMMARY OF THE INVENTION 
       [0012]    It is the objective of the invention to provide a novel means of dispensing fluidized alkaline metals into a hydrolyzation reaction chamber to generate electrons by the rupture of hydrogen bonds to the oxygen atom of the water molecule. 
         [0013]    It is another object of the invention to increase the acceleration of the rising slope of the amplitude curve of generated electrons to a spike in order to quicken the rate of the induced magnetic flux field cutting across the primary winding of an electrical transformer increasing the efficiency of the induction into the secondary winding of the said transformer. 
         [0014]    In overall intent it is the object of this invention to demonstrate the use of fluidized alkaline metal technology in its developing dominant role in electron production for electrical generation for mobile and field stationary systems and the appended usage of the expended electrolyte as a value added product when used as a photo steriochemical tool in chemical synthesis and in carbon capture at coal-fired facilities. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0015]    Four drawings are presented to describe the working mechanics of the invention and the theory of operation in an expanding technical field of new methods of electrical generation. 
           [0016]      FIG. 1  is a diagrammatic sketch of the two major mechanical working elements of of the simplex generator shown partially in cross-section. 
           [0017]      FIG. 2  is a graphic presentation of generated pulsed direct current spike and subsequent die-away dissipation flow. 
           [0018]      FIG. 3  is a box diagram of the system flow of simplex generators designated by a broken line boundary separating it from the comparative Ref. 1 multiplex generator systems. 
           [0019]      FIG. 4  is a detail drawing of the six major mechanical assemblies of the simplex generator process equipment which operates in unison. 
       
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       [0020]    The principal mechanical embodiments of the invention are presented in  FIG. 1  comprising a spindle shaft  1  rotatively mounted in block  2 . An aligned passage  3  passes through said block  2  and said spindle shaft  1 . When spindle shaft  1  is rotated at 30 rpm by a motor driven gear fixedly mounted on spindle shaft  1  by an assembly key inserted in slot  4  of spindle shaft  1  the flow through passage  3  is opened and closed sixty times per minute producing a 60 hz pulsing flow through passage  3  to outlet  5 . The media flowing through passage  3  is hereinafter characterized as finite quantities of equally spaced fluidized alkaline metals which pass in 60 hz pulses from outlet  5  of block  2  into injector  12  graphically represented in box flow diagram in  FIG. 3 . When shaft  1 , rotatively mounted in block  2 , is assembled with gearing and caused to rotate by an electric motor it is hereinafter termed a simplex generator  11  graphically represented in box diagram in  FIG. 3 . When the said simplex generator  11  is assembled on injector  12  the composite assembly is hereinafter termed a simplex injector system. 
         [0021]    Referring now to  FIG. 2  which is a graph of finite increments of electron (e − ) spiked curve  6  production (Qo initial charge) during hydrolysis of a fluidized alkaline metal and the intermediate interval of associated capacitor die-away (ε −bt ) residual current flow  7  (Qt charge at time t) shown in broken-line in capacitor tuyere  14  of  FIG. 3  such that Q t =Q oε   −bt  where b is a constant decrement leaking out of capacitors  16 . 
         [0022]    Turning now to  FIG. 3  which is a box flow diagram of both the simplex generator of the present system and the multiplex generator of Ref. 1. The said simplex generator which comprises the novel features of the present invention is shown as being contained within the broken-line boundary  8 . Fluidized metal from fuel reservoir  9  is pumped to pressure system  10 . Pressure system  10  is a low volume high pressure positive displacement pump which forces the said fluidized metal into the aligned passage  3  of simplex generator  11 . The simplex generator  11 , during each revolution of shaft  1  opening and closing aligned passage  3 , divides the flow through passage  3  into individual finite equal quantities of singular pulsed flow into injector  12  where it is sprayed with water and passed into live-steam in reaction chamber  13 . The electrons within the gaseous ionic charge flow from reaction chamber  13 ′ passing into capacitor tuyere  14  where the electrons are captured on strakes  15  and pass into a plurality of toroidal shape capacitors  16  positioned circumferentially about capacitor tuyere  14  chamber  28  forming a capacitor electron storage bank. The said capacitor  16  storage bank of capacitor bank  16  of  FIG. 4  producing the electron spikes  6  and capacitor die-away current flow  7  indicated in  FIG. 2 . 
         [0023]    A more detailed description of the simplex generator process flow is presented in  FIG. 4 . The pulsating flow of alkaline metals from simplex generator  11  passes into injector  12  through a high pressure water spray  17  and passes in 60 hz surging pressure spurts into live steam entering reaction chamber  13  from steam conduit  17 . The hydrolyzation of the fluidized alkaline metals from simplex generator  11  ruptures the hydrogen to oxygen bond of the water molecule producing charged ions and free electrons. The said free electrons are electro-statically captured by strakes  15  positioned around chamber  28  of capacitor tuyere  14 , said strakes being in electrical communication with a plurality of toroidal capacitors  16  connect in parallel with an electrical bus-bar  18  connected to a load transmission cable  19 . The said free electrons captured by the toroidal capacitors  16  pass through the load transmission cable  19  and are released to the primary winding of an electrical transformer. The said electrons from load cable  19  pass through the said primary winding as a 60 hz oscillating direct current having a cyclic amplitude  6  shown in  FIG. 2  corresponding to the electrochemical equivalent flow volume mass of the fluidized alkaline metals passing into injector  12  from simplex generator  11 . 
         [0024]    Referring momentarily to  FIG. 3 . The pulsating flow of alkaline metals from simplex generator  11  passes into injector  12  through a high pressure water spray  17  and is pressurized by the reaction in 60 hz surging spurts into live steam  24  shown in  FIG. 4  flowing into reaction chamber  13 . The said injected alkaline metal is completely hydrolyzed in said reaction chamber  13 . The said hydrolyzation ruptures the hydrogen bonds to the oxygen atom of the water molecule producing charged ions and free electrons. The said free electrons are electro-statically captured by capacitors  16  of tuyere  14  as shown in  FIG. 4 . The said free electrons captured by the capacitors  16  of tuyere  14  are released to the primary winding of an electrical transformer. The said electrons pass through the said primary winding as 60 hz pulsating direct current having an amplitude corresponding in electrochemical equivalents with the cyclic release in discrete volumetric flow pulses of alkaline metals passing into injector  12  from simplex generator  11 . 
         [0025]    Returning to  FIG. 1 . The sixty cycle opening and closing cycle flow events being formed in aligned passage  3  as a result of the 30 rpm rotation of shaft  1  produces a constantly varying flow volume of alkaline metals resulting in a quantitatively changing weight flow from outlet  5  to the injector as the alignment of passage  3  in block  2  changes with the alignment of passage  3  in spindle shaft  1  as it rotates in block  2 . The velocity of flow to outlet  5  also changes proportionately in non-compressible continuity with the changing flow area of passage  3  through spindle shaft  1  to outlet  5  during transition from opening and closing of passage  3 . Each opening event of channel  3  is separated by a much longer closed interval allowing sufficient time for complete hydrolyzation reaction of the alkaline metals injected into reaction chamber  13 . The hydrolyzation reactions of the said alkaline metals injected into reaction chamber  13  produce electrons, a large portion of which are absorbed by the capacitor circuits of capacitor tuyere  14  of Ref. 1 shown immediately downstream of reaction chamber  8  in  FIG. 3 . 
         [0026]    Turning now to  FIG. 2 . High intensity 60 hz electrical pulses are produced at discrete intervals by the cyclic hydrolyzation of individually separated small quantities of alkaline metals injected into reaction chamber  13 . In accordance with the conservation of energy as stated in the First Law of Thermodynamics the electro-equivalent current flow of electrons produced in the hydrolyzation of the injected alkaline metal in reaction chamber  13  is the same amount required during the electrolysis process that were required to reduce the alkaline metals to their pure state. The electrons released during the hydrolysis in reaction chamber  13  are depicted in  FIG. 2  as a series of steep spikes  6 , which fall quickly downward as a residual current flow  7  of the die-away retention of the capacitor banks  16  of the capacitor tuyere  14  of Ref. 1. The said die-away current  7  of the capacitor tuyere  14  also provide a continuity of flow between each current spike  6  and this residual flow is depicted as a broken line connecting electron flow between spikes. The closed cycle period electron flow  7  is maintained by the said die-current flow above the initial injection beginning flow. 
         [0027]    The novel features of the invention claimed are predominantly in the mechanical components of the simplex generator  11  shown in  FIG. 4 . Spindle shaft  1  rotatively mounted in block  2  is aligned with the bored passage  3  such that the said passage  3  is aligned with the bored passage  3  through spindle shaft  1 . The said rotatively mounted shaft  1  is fixedly attached to gear  20  by inserting a key into key slot  4 . Gear  20  is made to turn by gear motor  21  which operates through two 90° aligned reduction gearing sets  22 . Check valves  23  are positioned at the inlet and outlet  5  of aligned passage  3  in block  2 . 
         [0028]    Piston  26  of the pressure system  10  pump of  FIG. 4  is made to vertically reciprocate upward by eccentric cam  27  mounted on roller bearings on motor shaft  29 . Said cam  27  mounted within non-filling notch bearing  30 . Under high compression the ball bearing working within the non-filling notch is levered by inclined plane between bearings on both sides into circular alignment with its associate bearings. Piston  26  is made to move downward by spring  31  at which time the said notch bearing returns to its notched position causing piston  26  to drop to its BDC position. A plurality of electric heaters  32  are used to keep the pump structure, which acts as a heat sink, above the freezing point of the fluidized metals. 
       NUMBERED ELEMENTS OF THE INVENTION 
       [0000]    
       
           1 . Spindle shaft 
           2 . Block 
           3 . Aligned passage 
           4 . Key slot 
           5 . Outlet 
           6 . Electron spike 
           7 . Capacitor die-away flow 
           8 . Broken line boundary 
           9 . Fuel reservoir 
           10 . Pressure system 
           11 . Simplex generator 
           12 . Injector 
           13 . Reaction chamber 
           14 . Capacitor tuyere 
           15 . Strakes 
           16 . Toroidal capacitor bank 
           17 . High pressure water spray 
           18 . Bus-bar 
           19 . Load cable 
           20 . Gear 
           21 . Gear motor 
           22 . Reduction gearing set 
           23 . Check valve 
           24 . Live steam 
           25 . Cooling air 
           26 . Piston 
           27 . Cam 
           28 . Chamber 
           29 . Motor shaft 
           30 . Non-filling notch bearing 
           31 . Spring 
           32 . Electric heaters 
           33 . Multiplex Generator