Electro-magnetic flux valve

Abstract

The Electro-Magnetic Flux Valve (EMFV) is an electrically actuated permanent magnet field flux shunt comprised of a low reluctance ferromagnetic core, surrounding a permanent magnet, with at least two imbedded control element sections by which the permeance of the core can be reduced. When placed within an external closed magnetic circuit, the EMFV core, at quiescence, acts as a keeper to the magnetic flux of the magnet. When electrically activated, the EMFV core permeance is reduced and the permanent magnet flux is released to energize the external magnetic circuit. When the control signal is removed the EMFV core again becomes highly permeable and constrains the permanent magnet flux thus deenergizing the external magnetic circuit. The EMFV is intended to be an integral part of a Magnetic Power Converter.

Claims

1. An apparatus, comprising: a magnet completely surrounded by a ferromagnetic shunt core on four sides; at least two embedded flux control element sections within the shunt core such that when electrically energized a reluctance of the shunt core increases to a point of magnetic saturation.

2. The apparatus of claim 1, further comprising an external closed magnetic circuit electrically coupled configured for providing a flux path for the magnet when electrically energized.

3. The apparatus of claim 1, wherein the shunt core is formed in the same plane or orthogonally within a frame of an external magnetic circuit.

4. The apparatus of claim 1, wherein the shunt core is wider than a frame of an external magnetic circuit if it is oriented orthogonally.

5. The apparatus of claim 4, wherein the shunt core controls flux through the external magnetic circuit frame resulting from a wide shunt core cross section.

6. The apparatus of claim 1, wherein the two embedded flux control element sections within the shunt core is driven by a coil.

7. The apparatus of claim 1, wherein the two embedded flux control element sections within the shunt core are configured to actively moderate a total reluctance of the shunt core when energized.

8. The apparatus of claim 1, further comprising a coil traversing a first void and a second void, the first void on a positioned adjacent a first side of the magnet and the second void positioned adjacent a second side of the magnet, the coil, when energized, produces a localized magnetic field around the first void and the second void in the shunt core, wherein when the at least two embedded flux control elements are energized via the magnetic field.

9. An apparatus, comprising: a magnet surrounded by a ferromagnetic shunt core; at least two embedded flux control element sections within the shunt core such that when electrically energized a reluctance of the shunt core increases to a point of magnetic saturation; and a boost converter drive circuit configured to use an input power switch which isolates the boost converter circuit from a power source during a boost or a recovery phase of operation.

10. An apparatus, comprising: a magnet surrounded by a ferromagnetic shunt core; at least two embedded flux control element sections within the shunt core such that when electrically energized a reluctance of the shunt core increases to a point of magnetic saturation; and a boost converter drive circuit configured to use a passively charged bootstrap capacitor circuit at an input, wherein the passively charged bootstrap capacitor circuit is configured as a clamper to establish a boost voltage threshold during a recovery cycle.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The present disclosure can be better understood with reference to the following drawings. The elements of the drawings are not necessarily to scale relative to each other, emphasis instead being placed upon clearly illustrating the principles of the disclosure.

(2) FIG. 1 is an isometric view of the Electro-Magnetic Flux Valve (EMFV) according to an exemplary embodiment of the present disclosure.

(3) FIG. 2 illustrates an induction curve and the Stoletov curve for M19 electrical steel.

(4) FIG. 3 illustrates the induction curve and the Stoletov curve for Carp 49 electrical steel.

(5) FIG. 4 is a plan view of the EMFV placed within an external magnetic circuit which includes an output coil to measure flux density according to an exemplary embodiment of the present disclosure.

(6) FIG. 5 is a plan view of the EMFV, with the control elements at quiescence, showing the permanent magnet flux constrained within the EMFV shunt circuit.

(7) FIG. 6 is a plan view of the EMFV, with the control elements energized, showing the permanent magnet flux shifted out of the EMFV shunt circuit into the external magnetic circuit.

(8) FIG. 7 is an isometric view of the widened core version of the Electro-Magnetic Flux Valve (EMFV) according to an exemplary embodiment of the present disclosure.

(9) FIG. 8 is an isometric view of the widened core version of the Electro-Magnetic Flux Valve (EMFV) placed in an external frame according to an exemplary embodiment of the present disclosure.

(10) FIG. 9 is a simplified schematic diagram of the isolated boost circuit used to drive the EMFV according to an exemplary embodiment of the present disclosure operating in the Drive Cycle.

(11) FIG. 10 is a simplified schematic diagram of the isolated boost circuit used to drive the EMFV according to an exemplary embodiment of the present disclosure operating in the Recovery Cycle.

DETAILED DESCRIPTION

(12) The EMFV of the present disclosure of FIG. 4 consists of a permanent magnet encircled by a low reluctance ferromagnetic shunt core 14 (FIG. 1) composed of segments 41, 42, 46 and 47 that control the flux produced by the magnet 43. Two of the shunt core segments, 46 and 47, are configured to control a flux produced by the magnet 43. When the flux control segments 41, 42, 46, and 47 are electrically energized, their reluctance increases and the permanent magnet flux shifts from the shunt core to the external magnetic circuit core 44. The output coil 45 in the external magnetic circuit 44 is used to quantify the amount of flux that the EMFV is able to control.

(13) The present notional example shown in FIG. 1 employs an embedded coil 16 to form the two flux control segments in the shunt core 14. The coil 16, when energized, produces a localized magnetic field around each void 12 and 15 in the shunt core 14. The magnetic field causes the reluctance in the flux control segments 46 and 47 (FIG. 4) to increase toward saturation.

(14) The present notional example FIG. 1 has the voids in the control segments 12 and 15 placed off center with respect to the shunt core 14 to allow the outer flux path 17 to saturate before the inner flux path 18 thus providing linear control of the permanent magnet 13 flux through the shunt 14.

(15) In one embodiment, M19 electrical steel laminations may be used for the shunt 14. Note that FIG. 2 shows the Stoletov curve 21 for the M19, which indicates that even when saturated the material is still quite permeable. Note that other types of material may be used in other embodiments.

(16) In such an embodiment, the shunt core 14 may be fabricated with Carp 49 Permalloy. In FIG. 3 the Stoletov curve 31 for the Carp 49 Permalloy 31 shows a reduction in coercion force that achieves saturation and also demonstrates the drop in permeability above saturation.

(17) The magnetic flux control afforded by the present notional example FIG. 1 can be quantified when placed in an external magnetic circuit FIG. 4 and turned on and off. When the EMFV is deenergized the permanent magnet flux is constrained by the shunt core 14 as in FIG. 5. When the EMFV is energized the permanent magnet flux is free to energize the external magnetic circuit path as in FIG. 6.

(18) In one embodiment, the amount of flux that the EMFV can control may be determined by the cross section of the permanent magnet and the width of the ferromagnetic shunt core shown in FIG. 7. In this embodiment, the magnet 73 and the shunt core 74 are made wider and then placed in the external magnetic circuit orthogonally as depicted in FIG. 8 where the flux density in the external circuit would increase.

(19) The present notional example FIG. 1 is shown driven with a flux control coil 16. The flux control coil 16 and the ferromagnetic shunt core 14 together form an electromagnet which when energized acts to reinforce a flux field produced by the permanent magnet 13. When the flux control coil 16 is overdriven, beyond what is required to simply shift the permanent magnet flux into the external magnetic circuit as shown in FIG. 8, the extra flux produced by the electromagnet is passed into the external circuit to be added to the flux density quantified by the output coil 82.

(20) The EMFV is electrically driven to shift the permanent magnet flux out of the shunt core. The reactive power to overcome the inductance of the drive circuit is normally lost but in this case it may be recovered by the drive circuit to promote performance efficiency.

(21) The conventional boost converter circuit takes power from the source and boosts the voltage to be delivered to the load. The Isolated boost converter in this notional example is different in that the power taken from the input source battery is able to be largely recovered and returned to the same source battery to be reused. This is accomplished, as seen in FIG. 9, by modifying the input of the conventional circuit design with the addition of an isolation power switch Q1 and an integral bootstrap capacitor C1 to establish the boost voltage threshold to force the recovered charge back into the source battery in support of the Recovery Cycle as shown in FIG. 10.

(22) In FIG. 9 the Drive Cycle is initiated by switches Q1 and Q2 turning on simultaneously and supplying drive current from the DC Link capacitor C2 and the battery through D3 to the EMFV which begins to shift the permanent magnet flux out of the shunt core. The boost capacitor C1 is charged to the battery B1 potential passively through R1 in preparation for the Recovery Cycle. As the current flows through the EMFV the local flux builds until the control segments saturate at which point switches Q1 and Q2 open up and the magnetic flux which has built up collapses.

(23) In FIG. 10 the Recovery Cycle commences as the permanent magnet flux rushes back into the shunt core and induces a reverse polarity voltage into the EMFV control winding. The EMFV control winding voltage boosts the charge in the bootstrap capacitor C1 and conducts through D2 to charge the DC Link capacitor C2 which in turn transfers charge back to the battery through the saturable reactor L1. When the Recovery Cycle concludes the Drive Cycle begins again.

(24) The foregoing discussion discloses and describes exemplary methods and embodiments of the present disclosed disclosure. The disclosure is intended to be illustrative, but not limiting, of the scope of the apparatuses and methods, which are set forth in the following claims.