AU2012343328B2 - Magnetic inertia element heat reactor - Google Patents

Abstract

The disclosed magnetic inertia element heat reactor is a vertical stationery cylindrical element. With stationery electric prime-mover, the electric prime-mover driven axial (1), in electric prime- mover housing (4), supported by bearing (3) and (7). The bearing (7), secured to prime-mover base (10), its prime-mover housing having, integrated water circulation area (5/6) and 8 with water inlet (9) and a water flow to stationery steam producing area (17) via inlet (20) and to water spray jets (19). The water spray jets, positioned towards stationary magnetic or non magnetic multiple collision elements (16). The stationery steam producer having its multiple steam release valve (12). The steam producer base (17), secured to reactor base (21), its steam producer (17), having high temperature insulation (18), this is insulating the water circulation (20) and steam producer (17) wit areas between two collision elements (16), the insulation base is secured to reactor base (22) and the high temperatures insulation (18), being retained by shielding stabilizer (28). The magnetic inertia element heat reactor having a rotational shell (13) is secured to electric prime-mover axial (1) by securing element (2) and driven by electric prime-mover axial (1) and having multiple permanent-magnets (14) and (26), the permanent-magnet housing (11) secured to rotational shell (13) by securing element (25), the rotational shell (13) lower part secured to bearing (29) which is secured by element (30). The reactor having a vertical stationery water-reservoir (27), between two stationary multiplied collision element (16) and having air-gap (15), between rotational and stationery elements. The magnetic inertia element heat reactor base (23) is secured with securing element (24).

Description

WO 2013/075170 PCT/AU2012/001440 Magnetic Inertia Element Heat Reactor Invention related to permanent magnets centrifugal acceleration with pennanent magnet salient poles, and a magnetic inertia collision with multiplies magnetic and non-magnetic elements. Centrifugal acceleration of a permanent magnets, magnetic inertia lines, 5 Collision with multiplies magnetic and non-magnetic elements. Inertia line breaks off some proportional length, from each line collision at time first fsion exist, from a magnetic positive (N) and negative (S) vulnerable phases, the breaks of inertia length, has gat two (2) ends, it is forming two (2) fusion, van-a-ree joining to on line in specified open spays, it is one inertia line has gat three fusion, with one element collision. 10 SUMMARY OF THE INVENTION. In a preferred embodiment of multiple permanent magnets, the magnetic inertia lines collision with magnetic and non-magnetic multiple element the magnetic inertia line emanate, coupling with opposite polarity permanent magnet in waveforms. The waveforms only can achieved with permanent magnet salient poles, it is a configurations, one 15 rectangular permanent magnet has gat (2/3 or 4) salient poles. Centrifugal acceleration of multiple permanent magnets travelling one way. The magnetic inertia waveform, travelling between opposite polarity permanent magnets opposite way. A preferred embodiment of magnetic inertia waveforms, collision with magnetic and non-magnetic multiple elements. The inertia lines carry some heat from 20 collision exist, and dose heat veal release, in vertical stationery ceramic water-reservoir, specified open-spays. The magnetic inertia waveforms, compared to prior art apparatus. The invention embodiments related to centrifugal accelerations of multiple Permanent magnets, with permanent magnet salient poles, and magnetic inertia waveforms, collision with magnetic end non-magnetic multiple elements, with excessive heat from 25 multiple fusion. The required heat distribution achievable beyond several thousand Celsius, from number of magnets rotational ("rpm"). And put on a present invention, for Magnetic Inertia Element Heat Reactor, it is to provide energy for steam production, and to provide progress for manufactures, Hydrogen and Electricity Energy. It is additional features of the invention embodiments related to centrifugal 30 acceleration of a multiple permanent magnets. The magnetic inertia lines couplet with Earth magnetic inertia lines and canes jointly for collusion exist, the Earth magnetic inertia 1 WO 2013/075170 PCT/AU2012/001440 lines collision (%), it is proportional, will be described hereinafter and which will form, the subject of the claims appended hereto. BRIEF DESCRIPTION OF THE DRAWINGS. For the present invention, referred to the following detailed description of the S preferred embodiment, taken in conjunction with the accompanying drawings, in which element have been given like numerals, and wherein. FIG. 1. Shows a schematic vertical stationery elevation side view of the Magnetic Inertia Element Heat Reactor, according' to the present invention. FIG. 2. Shows a cross-sectional view of the vertical stationery Magnetic Inertia Element 10 Heat Reactor, shown in FIG.1. FIG. 3. Shows a lineal format cross-sectionals view of multiple permanent magnets, with multiple permanent magnet salient poles and a magnetic inertia waveforms, coupling with opposite polarity permanent magnets, according to the present invention. FIG. 3A. Shows a lineal format top sectional view of multiple permanent magnets, with 15 multiple permanent magnets salient poles, according to the present invention. FIG. 4. Shows a lineal format a cross-sectional view, of the multiple permanent magnets inertia waveforms, collision with multiple magnetic and non-magnetic elements, according to the present invention. DETAILED DESCRIPTION OF THE PREFERED EMBODIMENTS. 20 A preferred embodiment of a magnetic inertia element heat reactor, in vertical stationery elevation side view, shown in FIG. 1 and in a cross-sectional view, shown in FIG. 2 electric prim-mover driven axial 1, supported by bearing 3, in housing 4 and bearing 7, in prime-mover bays 10 and housing 6, secured to vertical stationery electric prime mover bays 10, with secures bolt 30, the embodiment shown in FIG. 1. According to 25 FIGS. 1 and 2 water circulation 5, 6 and 8, in vertical stationery electric prime-mover outer shell, with water inlet 9 and a water flows to stationery steam producer 20 and to water spray jets 19, are utilized in the preferred embodiment. In the preferred embodiment, a rotational shell 13, driven by stationery electric prim-mover axial 1 and supported by bearing 29, the bearing inner rotational part, secured 30 to vertical stationery prime-mower outer shell 6 and outer rotational part of the bearing, secured to rotational shell lower part 13, the top part of a rotational shell, secured to rotational axial 1, with lock nut 2, shown in FIG.l. In preferred embodiment the rotational multiplies permanent magnet and 2 WO 2013/075170 PCT/AU2012/001440 permanent magnet salient poles housing 11, secured to rotational shell 13, with secures element 25 shown in FIG. 1 and a multiplies permanent magnets shown in FIG. 2 and in lineal formats shown in FIGS. 3 and 3. A. In preferred embodiment apparatus 15 air gap, bat-win rotational 5 multiple permanent magnets 14 and stationery magnetic or non-magnetic multiple collision elements 16, shown in FIGS. 1 and 2. In preferred embodiment apparatus 16, a vertical stationery multiple magnetic or non-magnetic collision element disposing to word of rotational multiple permanent magnets 14 and 26 the multiple collision element- bays 21, secures to reactor bays 23, shown in FIG.1. 10 In preferred embodiment apparatus 17, the stationery steam producer water inlet 20, as shown in FIG. 1 and a water spray jets 19, emanates water spray direct on multiple collision elements outer-side and a pressurised steam production depending on a steam housing specification, the steam release valves 12, shown in FIGS. 1 and 2. In preferred embodiment apparatus 18, the high temperatures insulation housing, 15 shown in FIGS. 1 and 2 it is insulating the water circulation 20 and areas bat-win two multiple collision elements 16, the insulation housing bays 22, secures to reactor bays 23. In preferred embodiment a vertical stationery ceamic water-reservoir apparatus 27, specified open spays, bat-win two stationery multiplies collision element for recovering a rotational permanent magnet inertia lines, collision looses, and a heat carried 20 by a magnetic inertia lines, veal be release, in vertical stationery ceramic water-reservoir, specified open spays, shown in FIG. 2. In preferred embodiment apparatus 28, a shielding stabilizer, for high temperature insulation bat-win apparatus 14 and 16, the shielding element is perforated Stainless-steel, shown in FIG. 2. 25 The present invention as illustrated in FIGS. 1 / 2 /3 / 3A and 4. The permanent magnet inertia element heat reactor, can be applied to various area, where heat energy is necessary. A few particular suitable example (a) high-pressure steam for electricity energy manufactures, (c) hydrogen energy manufactures, (d) supper heat air production, (e) domestic steam heating system, (f) oil refinery intense heating 30 system, and varies furnaces heating apparatus. The foregoing description is directed to particular embodiment and methods of the present invention, comprise a supper-able heat temperatures beyond several thousand Celsius, and the following claims bee interpreted 3

Claims (8)

1.A vertical stationery permanent magnet inertia element heat reactor apparatus comprising: (a) wherein a supper-able heat temperatures beyond several thousand Celsius; b) wherein, having a vertical stationery electric prime-mover, rotational axial member one c) wherein having a water cooling circulation member five six and eight; in prime-mover outer shell, for reduction of a heat, produced by electric prime-mover .

2. The permanent magnet inertia element heat reactor apparatus as specified in claim 1, wherein, having a rotational member thirteen, and carried on axial by a first rotating member one, wherein having a rotational permanent magnet member fourteen and carried on a rotational member thirteen, wherein heaving a rotational permanent magnet salient poles member twenty-six and carried on a rotational member thirteen.

3. The permanent magnet inertia element heat reactor apparatus as specified in claim 2, wherein having a rotational member fourteen and twenty-six, permanent magnet and permanent magnet salient poles wherein, a rotational member twenty-six forming a magnetic inertia waveforms, between two opposite polarity rectangle permanent magnets as seen in lineal formats.

4. The permanent magnet inertia element heat reactor apparatus as specified in claim 3, (a) wherein having a rotational member twenty-six, a permanent magnet salient poles, has got a top-priority for controlling a rotational multiple permanent magnet inertia waveforms, the wave forms it is travelling true a cross sectional view of the rectangular permanent magnet pad, and coupling with opposite polarity permanent magnets in waveforms, as seen in lineal format (b) Magnetisation of rectangular permanent magnets, a cross sectional view, Magnetization Force' ("mf) and of magnetically conductive material portions.

5. The permanent magnet inertia element heat reactor apparatus as specified in claim 1, (a) wherein heaving a vertical stationery multiplies magnetic or non-magnetic collision elements member sixteen. The member sixteen disposing, for collision with magnetic inertia lines, of a rotational member fourteen, and twenty-six the magnetic inertia lines, jointly with Earth magnetic inertia lines, breaks off sum proportional length, from each line at time first fusion exist from magnetic positive (N) and negative (S) vulnerable phases, the breaks off inertia length has gat two ends, it is forming two fusion, van-are-ree joining to 4 on line in vertical stationery ceramic water-reservoir, specified open spays twenty-seven, wherein one inertia line has got its three fusion, with one clement collusion, and a heat energy is proportional, from each line collusion, jointly with Earth magnetic inertia lines.

6. The permanent magnet inertia element heat reactor apparatus as specified in claim 5, wherein heaving a two vertical stationery multiplied collusion elements sixteen and between a two multiplied collusion element, hawing a vertical stationery ceramic water reservoir twenty-seven, specified open spays wherein, for re-covering a multiplied rotational permanent magnet inertia lines collusion losses, and a heat carried from collusion by a magnetic inertia lines, veal be releases in vertical ceramic water-reservoir specified open spays.

7. The permanent magnet inertia element heat reactor apparatus as specified in claim 1, wherein having a vertical stationery steam producer, whit water in-let twenty and water spray-jets nineteen, it is emanates water spray direct to multiplied collusion elements outer side, and a pressurising steam production, a depending on a steam housing specifications.

8. The permanent magnet inertia element heat reactor apparatus as specified in claim 1, wherein having a vertical stationery high temperatures insulation housing eighteen, it is insulating the water circulation twenty, and aeries between two collusion elements sixteen, (a) having a vertical stationery high temperatures insulation shielding stabilizer twenty-eight (b) the insulation bays twenty-two, secures to reactor bays twenty-three wherein 5