The inventions disclosed herein and the inventions of U.S. application Ser. No. 14/559,817, filed Dec. 3, 2014 were subject to a joint research agreement between Wireless Advance Electrification, Inc. a corporation of Utah, and Utah State University.
Wireless power transfer provides many advantages over wired power transfer. Many devices and systems use wireless power transfer to charge batteries, deliver power, etc. without having to use a connector, which may fail over time. Situations where a device may require intermittent power transfer, for example, to charge a battery can benefit from wireless charging to alleviate problems associated with connector failure, breaching a waterproof or water resistant barrier, etc.
As wireless power transfer systems grow, power levels have increased. Conventional high-power wireless power transfer systems may require relatively high voltages for charging. Methods of reducing voltage requirements are desirable to reduce cost, voltage hazards, etc.
An apparatus for wireless power transfer is disclosed. The apparatus includes a first charging coil with a first conductor arranged in a winding pattern with a first winding around a center point and each successive winding of the first charging coil is further away from the center point than the first winding and any previous windings. A second charging coil includes a second conductor wound with respect to the first charging coil where each coil of the second charging coil is arranged between each winding of the first charging coil. The first charging coil and second charging coil are connected in parallel. A ferrite structure is positioned adjacent to the first charging coil and the second charging coil.
In one embodiment, each charging coil has an inner starting point. The inner starting point has a location where a first winding of a charging coil begins, and the first winding is closer to the center point than additional windings of the charging coil. The inner starting point of a charging coil for each charging coil is a same radius from the center point. In another embodiment, the inner starting point for each charging coil is spaced around a starting point circle equidistant from the inner starting point for other charging coils, the starting point circle centered about the center point.
In one embodiment, the apparatus includes an additional charging coil, and the additional charging coil includes an additional conductor wound with respect to the first charging coil, second charging coil, and any other additional charging coils, and each winding of an additional coil is arranged between each winding of the first charging coil and the second charging coil and any other additional charging coils, and each charging coil includes an inner starting point. The inner starting point is at a location where a first winding begins and the first winding is closer to the center point than additional windings of the charging coil. In the embodiment, the inner starting point for each charging coil is a same radius from the center point and the inner starting point for each charging coil is spaced around a starting point circle equidistant from the inner starting point for other charging coils. The starting point circle centered about the center point.
In one embodiment, each charging coil is wound so that at a particular radial from the center point each successive winding around an innermost winding is further from the previous winding and positioned substantially planar with respect to a line perpendicular to the center point. In another embodiment, each winding of each charging coil is arranged to be substantially planar. In another embodiment, each charging coil is arranged in an Archimedean spiral. In another embodiment, each charging coil is arranged in an irregular spiral, where the irregular spiral includes portions of a winding that vary in radius with respect to the center point other than variation between a starting point and an ending point of a winding to accommodate beginning of a next winding of the charging coil and to allow for windings of one or more additional charging coils. In a further embodiment, each charging coil is arranged in substantially a square shape and/or substantially a D-shape.
In one embodiment, at least a portion of a surface of the ferrite structure is planar and parallel to at least a portion of the first charging coil and second charging coil that are adjacent. In another embodiment, a side of the ferrite structure adjacent to the first charging coil and second charging coil is planar and the first charging coil and second charging coil are planar and are parallel to the side of the ferrite structure. In another embodiment, charging coils of the apparatus have a first portion positioned planar in a first plane and positioned adjacent to a section of the ferrite structure and the charging coils have a second portion positioned planar in a second plane and positioned adjacent to a planar section of the ferrite structure. The first plane and second plane are different planes. In another embodiment, the apparatus includes a second set of charging coils positioned adjacent to the first set of charging coils, where a portion of each of the first and second sets of charging coils are positioned adjacent and are positioned substantially in the first plane and portions of the first set of charging coils and the second set of charging coils positioned away from the adjacent sections of the first and second sets of charging coils are positioned substantially in the second plane.
In one embodiment, the conductor of each charging coil includes a first lead and a second lead. The first and second leads include portions of the conductor of each charging coil extending from windings of the charging coils. At least a portion of the first and second leads of each of the charging coils are grouped together in a pattern that adds inductance in addition to inductance of a winding portion of the charging coils or subtracts inductance from the inductance of a winding portion of the charging coils. The pattern is chosen to adjust a total amount of inductance of the charging coils. In another embodiment, ends of the first leads are connected and ends of the second leads are connected such that the charging coils are connected in parallel. In another embodiment, the ferrite structure includes a plurality of ferrite bars arranged in a radial pattern extending away from the center point.
An apparatus for wireless power transfer includes a first charging coil with a conductor arranged in a winding pattern with a first winding around a center point and each successive winding of the first charging coil is further away from the center point than the first winding and any previous windings. The apparatus includes one or more additional charging coils, where each charging coil includes a conductor wound with respect to the first charging coil where each coil of an additional charging coil is arranged between each winding of the first charging coil. The first charging coil and additional charging coils are connected in parallel.
Each charging coil has an inner starting point, where the inner starting point is at a location where a first winding of a charging coil begins and the first winding is closer to the center point than additional windings of the charging coil. The inner starting point for each charging coil is positioned a same radius from the center point. The inner starting point for each charging coil is spaced around a starting point circle equidistant from the inner starting point for other charging coils, and the starting point circle is centered about the center point. The first charging coil and the one or more additional charging coils are connected in parallel and the first charging coil and the one or more additional charging coils are substantially planar. The apparatus includes a ferrite structure positioned adjacent to the first charging coil and the one or more additional charging coils. At least one side of the ferrite structure is planar and is positioned adjacent to the first charging coil and the one or more additional charging coils.
A system for wireless power transfer includes a first charging coil with a first conductor arranged in a winding pattern with a first winding around a center point and each successive winding of the first charging coil is further away from the center point than the first winding and any previous windings. The system includes one or more additional charging coils, where each charging coil includes a conductor wound with respect to the first charging coil where each coil of an additional charging coil is arranged between each winding of the first charging coil. The first charging coil and additional charging coils are connected in parallel. The system includes a ferrite structure positioned adjacent to the first charging coil and the one or more additional charging coils, where the charging coils and ferrite structure are part of a charging pad. The system includes a resonant converter connected to the charging pad and providing power to the charging pad or a secondary circuit that receives power from the charging pad and conditions the power for a load.
In one embodiment, the charging pad is part of a primary charging pad and is connected to the resonant converter and the system includes a second charging pad. The second charging pad is connected to the secondary circuit. The system includes an energy storage device and/or a motor. The energy storage device and/or motor receive power from the secondary circuit.
In order that the advantages of the invention will be readily understood, a more particular description of the invention briefly described above will be rendered by reference to specific embodiments that are illustrated in the appended drawings. Understanding that these drawings depict only typical embodiments of the invention and are not therefore to be considered to be limiting of its scope, the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings, in which:
Reference throughout this specification to “one embodiment,” “an embodiment,” or similar language means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment. Thus, appearances of the phrases “in one embodiment,” “in an embodiment,” and similar language throughout this specification may, but do not necessarily, all refer to the same embodiment, but mean “one or more but not all embodiments” unless expressly specified otherwise. The terms “including,” “comprising,” “having,” and variations thereof mean “including but not limited to” unless expressly specified otherwise. An enumerated listing of items does not imply that any or all of the items are mutually exclusive and/or mutually inclusive, unless expressly specified otherwise. The terms “a,” “an,” and “the” also refer to “one or more” unless expressly specified otherwise.
Furthermore, the described features, structures, or characteristics of the invention may be combined in any suitable manner in one or more embodiments. In the following description, numerous specific details are provided, such as examples of programming, software modules, user selections, network transactions, database queries, database structures, hardware modules, hardware circuits, hardware chips, etc., to provide a thorough understanding of embodiments of the invention. One skilled in the relevant art will recognize, however, that the invention may be practiced without one or more of the specific details, or with other methods, components, materials, and so forth. In other instances, well-known structures, materials, or operations are not shown or described in detail to avoid obscuring aspects of the invention.
The schematic flow chart diagrams included herein are generally set forth as logical flow chart diagrams. As such, the depicted order and labeled steps are indicative of one embodiment of the presented method. Other steps and methods may be conceived that are equivalent in function, logic, or effect to one or more steps, or portions thereof, of the illustrated method. Additionally, the format and symbols employed are provided to explain the logical steps of the method and are understood not to limit the scope of the method. Although various arrow types and line types may be employed in the flow chart diagrams, they are understood not to limit the scope of the corresponding method. Indeed, some arrows or other connectors may be used to indicate only the logical flow of the method. For instance, an arrow may indicate a waiting or monitoring period of unspecified duration between enumerated steps of the depicted method. Additionally, the order in which a particular method occurs may or may not strictly adhere to the order of the corresponding steps shown.
The IPT charging systems 100 described herein may include a power factor stage 114, such as a primary alternating current (“AC”) to direct current (“DC”) power factor stage, fed from a voltage source 112, such as from a utility power grid. In some embodiments, a primary AC-DC converter stage may be configured to convert grid-level voltages to a DC voltage 116, such as a DC bus voltage, for a primary tuned resonant converter. A DC output voltage with low output ripple is preferred to large ripple systems in order to prevent an amplitude modulated signal appearing in the wireless inductive power transfer system which can cause reduced efficiency and require additional complexity.
In some embodiments, active power factor correction (“PFC”) in AC-DC converters may help to ensure the grid voltage and current are closely in phase. PFC may reduce overall grid current requirements and typically reduces grid harmonics. Grid power supply companies typically have certain harmonic requirements for attached industrial equipment. Often grid power supply companies also charge extra for power to industrial equipment that exhibits low power factor.
In the IPT charging system 100 described herein, one or more suitable stages may be used for PFC. For example, one or more commercial off-the-shelf (“COTS”) AC-DC high efficiency power factor corrected converters may be used. The grid voltage source 112 may be a wide range of voltage inputs including, for example, single-phase 240 VAC, three-phase 208 VAC, or three-phase 480 VAC. In another embodiment, a 400 VDC output may be used for this stage and 400 VDC is typically an efficient output for a nominal grid input of single-phase 240 VAC grid input. A single-phase 240 VAC grid voltage with a 30 A circuit (suitable for a 5 kW IPT system) is commonplace in the United States even in areas that do not support industrial three-phase voltages, and may be used with the IPT system 100.
For the IPT charging system 100, in one embodiment, the first stage 104 includes an LCL load resonant converter 118 controlled by a primary controller 120 that may receive feedback signals from and may send control signals to the LCL load resonant converter 118. A primary controller 120 may receive information from alignment sensors for position detection 122 and may communicate using wireless communications 124. The LCL load resonant converter 118 is coupled to a primary receiver pad 126 coupled to a secondary receiver pad 128 over an air gap 108. The secondary receiver pad 128 is connected to a parallel decoupling pickup shown as a secondary circuit 130 controlled by a secondary decoupling controller 132 that may receive feedback signals and may send control signals to the secondary circuit 130. The secondary decoupling controller 132 may also communicate with alignment sensors for position detection 136 for control and may communicate wirelessly 134. The secondary circuit 130 may connect to a load 110, such as a battery 138 and may charge the battery 138. The battery 138 may provide power to another load, such as a motor controller (not shown). The second stage 106 and load 110 may be located in a vehicle 140.
Other embodiments of an IPT system 102 may include wireless power transfer for other purposes, such as battery charging for consumer electronic devices, such as a cellular phone, an electric razor, an electric toothbrush, and the like. One of skill in the art will recognize other uses for wireless power transfer and other IPT systems.
The apparatus 200 includes a first charging coil 202 with a first conductor arranged in a winding pattern with a first winding around a center point 208 and each successive winding of the first charging coil is further away from the center point 208 than the first winding and any previous windings. The apparatus 200 also includes a second charging coil 204 with a second conductor wound with respect to the first charging coil 202 where each coil of the second charging coil 204 is arranged between each winding of the first charging coil 202. The first charging coil 202 and second charging coil 204 are connected in parallel. Connection of the first charging coil 202 and the second charging coil 204 in parallel is not shown for clarity. Typically leads from the charging coils 202, 204 are connected so that the charging coils 202, 204 are connected in parallel. While two charging coils 202, 204 are depicted in
Advantageously, by splitting a charging coil into two charging coils 202, 204 and connecting the charging coils 202, 204 in parallel, inductance is reduced with respect to a non-split design. A lower inductance requires less voltage to drive the charging coils 202, 204 so voltage requirements are less on the primary receiver pad 126 to deliver a same amount of power to the secondary receiver pad 128. A lower voltage may then allow a designer to eliminate a transformer, user parts with a lower voltage rating, etc.
The charging coils 202, 204 each include a conductor that is typically insulated. The insulation is typically rated for expected voltages, including spikes, transients, etc. The insulation keeps the conductors from contacting each other and from other grounded or ungrounded structures. The insulation may include a varnish, thermoplastic, nylon, cross-linked polyethylene, rubber, and other insulation materials known in the art. The conductors may be solid or stranded and may be flexible or solid. In one embodiment, the conductors are a litz wire to reduce skin effect. The litz wire may include numerous strands of wire where each strand is insulated. One of skill in the art will recognize other wire types, insulation, etc. suitable for wireless charging.
The apparatus 200 also includes a ferrite structure 206 positioned adjacent to the first charging coil 202 and the second charging coil 204. The ferrite structure 206, in one embodiment, includes a planar surface positioned adjacent to the charging coils 202, 204. Typically the apparatus 200 is part of a charging pad, such as the primary receiver pad 126 or secondary receiver pad 128 and the ferrite structure 206 is designed to enhance a magnetic field above the charging coils 202, 204 to improve coupling with another receiver pad (e.g. 126, 128). The ferrite structure 206 is depicted as circular with an opening in the center of the ferrite structure 206, but one of skill in the art will recognize that other designs may be used for the ferrite structure. As used herein, “ferrite structure” includes any structure of a material that may be magnetized or that may be used in a transformer, such as the loosely coupled transformers formed by the primary receiver pad 126, the secondary receiver pad 128, and air gap 108 of
For example,
In one embodiment, each charging coil 202, 204 had an inner starting point. The inner starting point 210 of the first charging coil 202 and the inner starting point 212 of the second charging coil 204 are shown in
In another embodiment, the inner starting point for each charging coil is spaced around a starting point circle 216 equidistant from the inner starting point for other charging coils. The starting point circle 216 is centered about the center point 208, and in one embodiment, has a radius 214 that is the same radius 214 as the inner starting points 210, 212 of the charging coils 202, 204. For example, with two charging coils, e.g. the first charging coil 202 and the second charging coil 204, the inner starting points 210, 212 are 180 degrees apart around the starting point circle 216. For three charging coils the inner starting points may be spaced 120 degrees apart, for four charging coils the inner starting points may be spaced 90 degrees apart, etc.
In one embodiment, each charging coil 202, 204 is wound so that at a particular radial 218 from the center point 208, each successive winding around an innermost winding is further from the previous winding and positioned substantially planar with respect to a line perpendicular to the center point 208 so that the plane is perpendicular to the line. For example, the charging coils 208 may be arranged as in
In one embodiment, each charging coil 202, 204 is arranged in an Archimedean spiral. An Archimedean spiral, also known as an arithmetic spiral, is constructed of a locus of points corresponding to the locations over time of a point moving away from a center point 208 with a constant speed along a line which rotates with constant angular velocity. In another embodiment, each charging coil 202, 204 is arranged in an irregular spiral. The irregular spiral may include portions of a winding that vary in radius with respect to the center point 208 other than variation between a starting point and an ending point of a winding to accommodate beginning of a next winding of the charging coil and to allow for windings of one or more additional charging coils.
As described above, other designs may include more than two charging coils.
Note that the multiple coil design may include a non-integer number of turns because the ending point of a charging coil (e.g. 202) may be anywhere with respect to the inner starting point (e.g. 210). If a coil design with one charging coil has 11 turns, where a coil design has two charging coils (e.g. 202, 204), each can have 5.5 turns. Also, for a two charging coil design, the self inductance of each charging coil is roughly four times less than the self inductance of a design with a single charging coil. Comparing a single charging coil design and a two charging coil design, self inductance is related by equation (1).
However, the two split spiral charging coils are mutually coupled and the coupling coefficient is typically quite high and close to 1, then the mutual inductance between the two charging coils (e.g. 202, 204) is nearly the same as the self inductance. As a result, if the two charging coils 202, 204 are excited with the same phase current, the equivalent self inductance is:
If the two coils are connected in parallel (Leq∥Leq), the resulting inductance is roughly 4 times the original. For N split coils, the new pad inductance reduces by N2. Using this unique method of splitting the Archimedean spiral, the self inductances of the charging coils are nearly identical. This is beneficial because if there is a mismatch (e.g. between L1 and L2 in
A consideration for a split charging coil design is if there is any imbalance in coupling between the split primary charging coils to the secondary charging coil, especially if there is misalignment between the charging coils, and the center of the two Archimedean spirals are not perfectly matched due to the splitting technique. A study comparison of a coupling variation k of 10% between the coils L1 and L2 of
As can be seen in
Another method to control leakage inductance of the first charging coil 202 and second charging coil 204 is proposed.
Controlling inductance of the power leads 802 may be useful to adjust inductance of the charging coils 202, 204.
A test apparatus (not shown) such as the apparatus 201 depicted in
Self inductance LA is determined by measuring inductance of the first charging coil 202 while the second charging coil 204 and the secondary receiver pad 128 are open circuited. Self inductance LB is determined by measuring inductance of the second charging coil 204 while the first charging coil 202 and the secondary receiver pad 128 are open circuited. Mutual inductance LAB is measured on the first charging coil 202 while the second charging coil 204 is shorted and the secondary receiver pad 128 is not present. Mutual inductance LAS is measured on the first charging coil 202 with secondary receiver pad 128 short circuited and the second charging coil 204 open circuited. Mutual inductance LBS is measured on the second charging coil 204 with secondary receiver pad 128 short circuited and the first charging coil 202 open circuited. Mutual inductance LS1 is measured on the secondary receiver pad 128 with the first and second charging coils 202, 204 short circuited. Self inductance LS2 is measured on the secondary receiver pad LS2 with the first and second charging coils 202, 204 open circuited. The results are shown in Table 1.
“Z” is the height of the air gap 108, and “X” and “Y” are horizontal variations of the secondary receiver pad 128 with respect to a fixed primary receiver pad 126 with the first and second charging coils 202, 204. Coupling coefficients were then calculated from the measured self and mutual inductances. “kAS” is the coupling coefficient between the first charging coil 202 and the secondary receiver pad 128 and “kBS” is the coupling coefficient between the second charging coil 204 and the secondary receiver pad 128. “k2” is the coupling coefficient between the secondary receiver pad 128 and the combined inductance of the first and second charging coils 202, 204.
From Table 1, mismatch in coupling between the primary receiver pad 126 with first and second charging coils and the secondary receiver pad 128 is much less than 10 percent. In practice, throughout all the misalignment conditions in the X/Y plane, it was found that at maximum misalignment, coupling is around 5%. In practice, it was also found that the coupling between the two primary charging coils 202, 204 is around 0.75 which means leakage inductance on a real system is more likely to be around 25%. This is true even while using the inductance cancellation scheme in
When the test system was energized under full power and under worst case misalignment conditions at maximum output power on the secondary, the observed mismatch in primary current was less than 5%. This is negligible for practical pad systems. Hence, by using this technique the drive voltage for the resonant stage was reduced by half and eliminated an expensive transformer, without much downside to the overall system.
One other advantage of using split charging coils wired in parallel is that each primary split charging coil can be energized by a modular H-bridge, or other converter stage, and is stackable. This would require the converter stages to be synchronized, but the system would have a high operational availability with N+1 redundancy, meaning that if one converter stage failed (e.g. as an H-bridge converter stage) out of N stages, then the system can continue to operate with N−1 stages, or for N+1 stages and N stages running, if one stage failed, a backup stage may automatically take over.
A split charging coil design may also be used for other charging coil configurations.
Also in the embodiments of
An embodiment of
However, the design of
The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
This application claims the benefit of U.S. Provisional Patent Application No. 62/186,257 entitled “LOW INDUCTANCE PAD WINDING USING A MATCHED WINDING OF MULTIPLE SPIRALS” and filed on Jun. 29, 2015 for Patrice Lethellier, et al., which is incorporated herein by reference for all purposes.
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