• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    An energy management system for a motor vehicle has a first voltage supply terminal having a first nominal voltage and a second voltage supply terminal having a second nominal voltage. At least one of the first and second voltage supply terminals has a battery. A universal bi-directional DC-DC converter is coupled to exchange energy between the first and second voltage supply terminals. A third voltage supply terminal is provided for exchanging energy between the DC-DC converter and an external vehicle electrical system or battery charger. The energy exchanged between the first or second voltage supply terminals and the third voltage supply terminal is independent of the voltage and polarity of the external vehicle electrical system or battery charger.
    公开号:US20010004205A1
    申请号:US09/741,988
    申请日:2000-12-20
    公开日:2001-06-21
    发明作者:Peter Miller
    申请人:Motorola Inc;
    IPC主号:H02J7-1423
    专利说明:
    [0001] This invention relates to energy management systems and particularly but not exclusively to such systems for motor vehicles employing dual voltage electrical schemes. [0001] BACKGROUND OF THE INVENTION
    [0002] Many motor vehicle electrical systems are now being designed with a dual voltage schemes requiring two batteries having nominal voltages of 14 V and 42 V (12 V and 36 V rated batteries respectively) as shown in FIG. 1. The 12 V battery [0002] 40 typically has a high amp-hour rating and is used to provide energy to 14 V loads 50 such as lighting circuits and other circuits which are difficult to implement at higher voltages. The 36 V battery 80 typically has a high cranking current capability and is coupled to a 42 V generator and higher voltage loads 70, which may include the engine starter motor.
    [0003] In the event that one or other of these batteries becomes depleted of charge, there is a need to transfer power between them in a bi-directional manner. In order to do this, it is known to provide a conventional bi-directional DC-DC converter [0003] 60, coupled between the 12 V battery 50 and the 36 V battery 80. The bi-directional DC-DC converter 60 acts as a step-down converter (right to left in FIG. 1) or a step-up converter (left to right in FIG. 1) through switching charge through an inductor in a well known manner.
    [0004] An external ‘start aid’ post [0004] 10 is also provided, to enable an external means of charging the batteries. A switch 30 switches between the start aid post 10 and the 12 V battery 40, and a fuse and diode arrangement 20 is coupled between the switch 30 and the start aid post 10. When a positive DC voltage is applied to the start aid post 10, the switch 30 isolates the 12 V battery 40 and the DC voltage is coupled through the fuse and diode arrangement 20 to charge the 36 V battery 80 via the bi-directional DC-DC converter 60. When the DC voltage is removed from the start aid post 10, the switch 30 isolates the start aid post 10 and re-couples the 12 V battery 40 to the bidirectional DC-DC converter 60, whereupon (if necessary) the 12 V battery 40 is charged by the 36 V battery 80 via the bidirectional DC-DC converter 60.
    [0005] FIG. 2 shows the internal architecture of the bi-directional DC-DC converter [0005] 60, which has a first path 100 coupled to the 36 V battery 80 (not shown), a second path 170 coupled to the 12 V battery 40 (not shown), first and second switches 130 and 150 respectively and an inductor 140. The first and second switches 130 and 150 respectively are coupled in series between the first path 100 and earth. The inductor 140 is coupled between the second path 170 and a node between the first and second switches 130 and 150 respectively. The switches are switched by control logic in one of two ways: to transfer energy from the first path 100 to the second path 170 (step-down); and to transfer energy from the second path 170 to the first path 100 (step-up). Both of these are achieved by switching charge through the inductor 140.
    [0006] A problem with this arrangement is that for it to function correctly as a step-up converter, the first path [0006] 100 (and hence the 36 battery 80) must be at a higher potential than the second path 170, otherwise the intrinsic body diode 135 of the first switch 130 will conduct. Therefore if the 36 V battery 80 is faulty, greatly discharged or replaced by a new battery, and therefore has a voltage less than that of the 12 V battery 40 (or the start aid post 10, if appropriate), then the current flow will be uncontrolled, with potentially catastrophic results. It is possible to prevent this current flow by adding another switch in inverse series with the first switch 130, but this would still not enable charging in this state. This problem is compounded by the emergence of vehicles with an exclusively 42 V electrical system, because such vehicles cannot be used to provide a jump-start via the start aid post 10.
    [0007] A further problem is that by adding an additional switch the DC-DC converter [0007] 60, the circuit of FIG. 1 would require 7 MOSFETs (metal-oxide semiconductor field-effect transistors), as the change-over switch in the start aid post 10 requires 2 sets of inverse series MOSFETs, in addition to the three required in the DC-DC converter 60.
    [0008] There is therefore a need for a more flexible arrangement which enables a two-battery vehicle to re-charge either battery from the other, and which also provides improved flexibility for to charge and be charged via a start aid post. [0008]
    [0009] This invention seeks to provide a DC-DC converter and energy management system which mitigate the above mentioned disadvantages. [0009] SUMMARY OF THE INVENTION
    [0010] According to a first aspect of the present invention there is provided a DC-DC converter for use with an energy management system of a motor vehicle, comprising: first and second voltage supply terminals having first and second nominal voltages respectively, at least one of the first and second voltage supply terminals being arranged for coupling to a battery; and a third voltage supply terminal for exchanging energy with an external energy means; wherein the DC-DC converter is arranged to exchange energy between the first or second voltage supply terminals and the third voltage supply terminal independent of the voltage and polarity of the external energy means. [0010]
    [0011] According to a second aspect of the present invention there is provided an energy management system for a motor vehicle, comprising: first and second voltage supply terminals having first and second nominal voltages respectively; at least one battery coupled to at least one of the first and second voltage supply terminals; a universal bi-directional DC-DC converter coupled between the first and second voltage supply terminals for exchanging energy therebetween; and a third voltage supply terminal for exchanging energy between the DC-DC converter and an external energy means; wherein the energy exchanged between the first or second voltage supply terminals and the third voltage supply terminal is independent of the voltage and polarity of the external energy means. [0011]
    [0012] Preferably the universal bi-directional DC-DC converter comprises five switches, an inductor and control logic arranged such that energy is exchanged via step-up and step-down conversion from the first to the second voltage supply terminal and from the second to the first voltage supply terminal. The switches of the universal bi-directional DC-DC converter are preferably implemented using Metal Oxide Semiconductor Field Effect Transistors, and preferably at least two of the Metal Oxide Semiconductor Field Effect Transistors are implemented as a pair of inverse series transistors. [0012]
    [0013] Preferably the external energy means is an electrical system of another vehicle, such that the energy management system is coupled to exchange energy with the electrical system of the other vehicle. The exchange of energy is preferably the charging of a battery of the electrical system of the other vehicle by the energy management system. Alternatively the exchange of energy is the charging of the at least one battery by the electrical system of the other vehicle. [0013]
    [0014] Alternatively the external energy means is preferably a battery charger coupled to charge the energy management system. Preferably the nominal voltages of the first and second voltage supply terminals are 12 volts and 36 volts respectively. [0014]
    [0015] In this way an energy management system is provided for a two-battery vehicle in which either battery may be re-charged from the other, and in which a start aid post may also be used to charge one or other battery and be charged by one or other battery, irrespective of voltage or polarity. The system is also simply implemented with a minimum number of switches. [0015] BRIEF DESCRIPTION OF THE DRAWINGS
    [0016] An exemplary embodiment of the invention will now be described with reference to the drawings in which: [0016]
    [0017] FIG. 1 shows a prior art energy management system; [0017]
    [0018] FIG. 2 shows a circuit diagram of the prior art energy management system of FIG. 1; and, [0018]
    [0019] FIG. 3 shows a preferred embodiment of an energy management system in accordance with the invention. [0019] DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT
    [0020] Referring to FIG. 3, there is shown a universal bi-directional DC-DC converter [0020] 200 forming part of an energy management system of a motor vehicle electrical system having 36 V and 12 V circuits. The system 200 comprises an inductor 230 and five switches implemented using MOSFETs: 210 (first), 220 (second), 240 (third) and 250 (fourth) switches use single MOSFETs, and the fifth switch 260 uses an inverse series pair formed by MOSFETs 262 and 270. Each of the MOSFETs have an inherent body diode 215, 225, 245, 255, 265 and 275 respectively.
    [0021] The first switch [0021] 210 has a first conducting electrode coupled to a 36 V terminal 205 (which in turn is coupled to a 36 V battery (not shown)) and a second conducting electrode coupled to a first terminal of the inductor 230. The second switch 220 has a first conducting electrode coupled to the first terminal of the inductor 230, and a second conducting electrode coupled to a ground terminal 300.
    [0022] The third switch [0022] 240 has a first conducting electrode coupled to a second terminal of the inductor 230, and a second conducting electrode coupled to a ground terminal 300. The fourth switch 250 has a first conducting electrode coupled to a 12 V terminal 290 (which in turn is coupled to a 12 V battery (not shown)) and a second conducting electrode coupled to the second terminal of the inductor 230.
    [0023] The fifth switch is formed by first and second MOSFETs [0023] 262 and 270. The first MOSFET 262 has a first conducting electrode coupled to the second terminal of the inductor 230 and a second conducting electrode. The second MOSFET 270 has a first conducting electrode coupled to the second conducting electrode of the first MOSFET 262 and a second conducting electrode coupled to a start aid terminal 280, to which the battery of another vehicle or a battery charger (not shown) can be connected for the purpose of jump-starting. In this way the fifth MOSFET 260 and the sixth MOSFET 270 form the switch 260 for the purpose of switching the start aid terminal 280.
    [0024] In this way the first, second, third and fourth switches [0024] 210, 220, 240 and 250 respectively, form a universal bidirectional step-up/step-down converter between the 36 V battery and the 12 V battery (not shown), and the fifth switch 260 provides a path to a start aid post, the path being integrated with the DC-DC converter.
    [0025] Each of the switches [0025] 210, 220, 240, 250 and the two MOSFETs 262 and 270 have a control electrode coupled to control logic (not shown). The control logic manages the switching of the switches 210, 220, 240, 250 and 260 in a manner to be further described below.
    [0026] In operation, the DC-DC converter [0026] 200 is arranged to function in a number of modes, in dependence upon the voltages at the 36 V terminal 205, the start aid terminal 280 and the 12 V terminal 290. The control logic uses these voltages to choose a configuration which satisfies the required transfer of charge, and to select this configuration by setting the switches 210, 220, 240, 250 and 260 accordingly. The configurations and their respective switch settings are as follows:
    [0027] a) Step-down from 36 V battery terminal [0027] 205 to 12 V battery terminal 290: The first and second switches 210 and 220 respectively are switched in antiphase, the third and fifth switches 240 and 260 respectively are held in a non-conductive state and the fourth switch 250 is held in a conductive state. It should be noted that only the first switch 210 need be switched, because of the body diodes. However switching the second switch 220 increases the efficiency using a well known technique of active rectification. This basic approach is true for all the states below, the following configurations will assume that active rectification is always used.
    [0028] b) Step-down from 12 V battery terminal [0028] 290 to 36 V battery terminal 205 (when the 36 V battery is depleted to a terminal voltage of less than 12 V): The third and fourth switches 240 and 250 respectively are switched in antiphase, the first switch 210 is held in a conductive state and the remaining switches are held in a non-conductive state.
    [0029] c) Step-up from 12 V battery terminal [0029] 290 to 36 V battery terminal 205: The first and second switches 210 and 220 respectively are switched in antiphase, the fourth switch 250 is held in a conductive state and the remaining switches are held in a non-conductive state.
    [0030] d) Step-up from start aid terminal [0030] 280 to 36 V battery terminal 205: The first and second switches 210 and 220 respectively are switched in antiphase, the fifth switch 260 is held in a conductive state, and the remaining switches are held in a non-conductive state.
    [0031] e) Step-down from start aid terminal [0031] 280 to 36 V battery terminal 205 (when the 36 V battery has a terminal voltage of less than that of the start aid terminal 280): The third and fifth switches 240 and 260 respectively are switched in antiphase, the first switch 210 is held in a conductive state, and the remaining switches are held in a non-conductive state.
    [0032] f) Invert (step up or down) from start aid terminal [0032] 280 to 12 V battery terminal 290: The fourth and fifth switches 250 and 260 respectively are switched in antiphase, the second switch 220 is held in a conductive state and the remaining switches are held in a non-conductive state.
    [0033] g) Step down from 36 V battery terminal [0033] 205 to start aid terminal 280: The first and second switches 210 and 220 respectively are switched in antiphase, the fifth switch 260 is held in a conductive state and the remaining switches are held in a non-conductive state.
    [0034] h) Step up from 36 V battery terminal [0034] 205 to start aid terminal 280: The third and fifth switches 240 and 260 respectively are switched in antiphase, the first switch 210 is held in a conductive state and the remaining switches are held in a non-conductive state.
    [0035] i) Invert from 12 V battery terminal [0035] 290 to start aid terminal 280: The fourth and fifth switches 250 and 260 respectively are switched in antiphase, the second switch 220 is held in a conductive state and the remaining switches are held in a non-conductive state. It will be evident that this is the same configuration as f) above but with the energy flow in the other direction.
    [0036] In this way the start aid terminal [0036] 280 can accept any positive voltage and provide energy to the 36 V terminal 205, and can accept a negative voltage and use an inverting configuration to provide energy to the 12 V terminal 290. Once either the 12 V or 36 V battery is charged this can be used to charge the other battery without use of the start aid terminal 280. It will also be seen that the start aid terminal 280 can be used as a source of power of any (reasonable) voltage and polarity (for example to jump start another vehicle or to provide power to an electrical accessory). It is possible that the start aid terminal 280 could be coupled to an internal electrical socket such as a conventional cigarette lighter socket, and could thus be used to provide DC voltage to accessories plugged into the socket. As all of the switches are present active rectification is possible in all configurations, providing high efficiency.
    [0037] It will be appreciated that that some configurations may be used simultaneously. For example operations a) and g) can occur simultaneously by also switching the fourth and sixth switches [0037] 250 and 260 respectfully (thus giving energy to both the 12 V battery terminal 290 and to the start aid terminal 280 simultaneously, which is not possible in the prior art arrangement of FIG. 1).
    [0038] As can be seen from FIG. 3, six MOSFETs (or equivalent switches) are used to implement both the universal DC-DC converter and the start aid terminal [0038] 280 switching. This implementation provides for operation in any battery state and for jump starting from any reasonable voltage, with one less switch (seven switches are required in the prior art arrangement of FIGS. 1 and 2). Furthermore by providing further MOSFETs in inverse series with the MOSFETs forming the third and fourth switches 240 and 250 respectively (thus making the switch arrangement of the 12 V terminal 290 similar to that of the start aid terminal 280), reverse 12 V battery protection is also achieved.
    [0039] Therefore vehicles having electrical systems employing widely differing voltages, such as motorcycles (6 V), conventional vehicles (12 V), trucks (24 V) and new vehicles (42 V), are able to provide a jump-start to the motor vehicle, and are able to receive a jump-start from the motor vehicle, via the start aid terminal [0039] 280.
    [0040] It will be appreciated that alternative embodiments to the one described above are possible. For example, the voltages of the motor vehicle electrical system may differ from those described above in terms of nominal voltage values and number of batteries. For example, rather than the two batteries described above, it is possible to use a single battery (for example a 36 V battery) for one voltage terminal and a capacitor bank or similar charge storage arrangement for the other voltage terminal. [0040]
    [0041] Furthermore the implementation may differ from that described above. An alternative to the MOSFET technology described above, such as Insulation Gate Bipolar Transistors (IGBTs) could be utilised. [0041]
    权利要求:
    Claims (20)
    [1" id="US-20010004205-A1-CLM-00001] 1. A DC-DC converter for use with an energy management system of a motor vehicle, comprising:
    first and second voltage supply terminals having first and second nominal voltages respectively, at least one of the first and second voltage supply terminals being arranged for coupling to a battery; and
    a third voltage supply terminal for exchanging energy with an external energy means;
    wherein the DC-DC converter is arranged to exchange energy between the first or second voltage supply terminals and the third voltage supply terminal independent of the voltage and polarity of the external energy means.
    [2" id="US-20010004205-A1-CLM-00002] 2. The DC-DC converter of
    claim 1 wherein the universal bi-directional DC-DC converter comprises five switches, an inductor and control logic arranged such that energy is exchanged via step-up and step-down conversion from the first to the second voltage supply terminal and from the second to the first voltage supply terminal.
    [3" id="US-20010004205-A1-CLM-00003] 3. The DC-DC converter of
    claim 1 wherein the switches of the universal bi-directional DC-DC converter are implemented using Metal Oxide Semiconductor Field Effect Transistors.
    [4" id="US-20010004205-A1-CLM-00004] 4. The DC-DC converter of
    claim 3 wherein at least two of the Metal Oxide Semiconductor Field Effect Transistors are implemented as a pair of inverse series transistors.
    [5" id="US-20010004205-A1-CLM-00005] 5. The DC-DC converter of
    claim 1 wherein the external energy means is an electrical system of another vehicle, such that the energy management system is coupled to exchange energy with the electrical system of the other vehicle.
    [6" id="US-20010004205-A1-CLM-00006] 6. The DC-DC converter of
    claim 5 wherein the exchange of energy is the charging of a battery of the electrical system of the other vehicle by the energy management system.
    [7" id="US-20010004205-A1-CLM-00007] 7. The DC-DC converter of
    claim 5 wherein the exchange of energy is the charging of the at least one battery by the electrical system of the other vehicle.
    [8" id="US-20010004205-A1-CLM-00008] 8. The DC-DC converter of
    claim 1 wherein the external energy means is a battery charger coupled to charge the energy management system.
    [9" id="US-20010004205-A1-CLM-00009] 9. The DC-DC converter of
    claim 1 wherein the external energy means is an accessory coupled to the third voltage terminal via a cigarette lighter socket of the vehicle.
    [10" id="US-20010004205-A1-CLM-00010] 10. The DC-DC converter or system of
    claim 1 wherein the nominal voltages of the first and second voltage supply terminals are 36 volts and 12 volts respectively.
    [11" id="US-20010004205-A1-CLM-00011] 11. An energy management system for a motor vehicle, comprising:
    first and second voltage supply terminals having first and second nominal voltages respectively;
    at least one battery coupled to at least one of the first and second voltage supply terminals;
    a universal bi-directional DC-DC converter coupled between the first and second voltage supply terminals for exchanging energy therebetween; and
    a third voltage supply terminal for exchanging energy between the DC-DC converter and an external energy means;
    wherein the energy exchanged between the first or second voltage supply terminals and the third voltage supply terminal is independent of the voltage and polarity of the external energy means.
    [12" id="US-20010004205-A1-CLM-00012] 12. The system of
    claim 11 wherein the universal bidirectional DC-DC converter comprises five switches, an inductor and control logic arranged such that energy is exchanged via step-up and step-down conversion from the first to the second voltage supply terminal and from the second to the first voltage supply terminal.
    [13" id="US-20010004205-A1-CLM-00013] 13. The system of
    claim 11 wherein the switches of the universal bi-directional DC-DC converter 200 are implemented using Metal Oxide Semiconductor Field Effect Transistors.
    [14" id="US-20010004205-A1-CLM-00014] 14. The system of
    claim 13 wherein at least two of the Metal Oxide Semiconductor Field Effect Transistors are implemented as a pair of inverse series transistors.
    [15" id="US-20010004205-A1-CLM-00015] 15. The system of
    claim 11 wherein the external energy means is an electrical system of another vehicle, such that the energy management system is coupled to exchange energy with the electrical system of the other vehicle.
    [16" id="US-20010004205-A1-CLM-00016] 16. The system of
    claim 15 wherein the exchange of energy is the charging of a battery of the electrical system of the other vehicle by the energy management system.
    [17" id="US-20010004205-A1-CLM-00017] 17. The system of
    claim 15 wherein the exchange of energy is the charging of the at least one battery by the electrical system of the other vehicle.
    [18" id="US-20010004205-A1-CLM-00018] 18. The system of
    claim 11 wherein the external energy means is a battery charger coupled to charge the energy management system.
    [19" id="US-20010004205-A1-CLM-00019] 19. The system of
    claim 11 wherein the external energy means is an accessory coupled to the third voltage terminal via a cigarette lighter socket of the vehicle.
    [20" id="US-20010004205-A1-CLM-00020] 20. The system of
    claim 11 wherein the nominal voltages of the first and second voltage supply terminals are 36 volts and 12 volts respectively.
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    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    EP1289106A1|2001-08-29|2003-03-05|Toyota Jidosha Kabushiki Kaisha|DC-DC converter|
    FR2833113A1|2001-11-30|2003-06-06|Valeo Equip Electr Moteur|Reversible DC-DC converter for dual voltage vehicle supply network uses Zener diode to protect low-voltage side of converter and converter itself|
    US6642633B1|2001-06-27|2003-11-04|Yazaki North America, Inc.|Power management assembly|
    FR2848033A1|2002-12-03|2004-06-04|Renault Sas|Dual voltage supplying system for vehicle e.g. tourist vehicle, has control unit that controls conversion electronic transferring energy between primary and secondary networks based on states respective electrical systems|
    US6977488B1|2002-09-27|2005-12-20|Texas Instruments Incorporated|DC-DC converter|
    WO2006059017A1|2004-12-03|2006-06-08|Jean-Paul Siaudeau|Battery coupler|
    JP2007507995A|2003-10-06|2007-03-29|シーメンス アクチエンゲゼルシヤフト|Switching device for bidirectional equal charging between energy stores and method of operating the same|
    US20100148587A1|2008-12-17|2010-06-17|Alireza Khaligh|Multiple-input dc-dc converter|
    US7808211B2|2003-10-23|2010-10-05|Schumacher Electric Corporation|System and method for charging batteries|
    CN102088198A|2009-12-04|2011-06-08|三星Sdi株式会社|Energy storage system|
    US20110149611A1|2009-12-21|2011-06-23|Intersil Americas Inc.|Bidirectional signal conversion|
    CN103348126A|2011-02-03|2013-10-09|宝马股份公司|Motor vehicle comprising jump start device|
    US20130293005A1|2010-09-24|2013-11-07|Magna Steyr Fahrzeugtechnik Ag & Co Kg|Electric motor vehicle and redox flow module and cartridge therefor|
    EP2717417A1|2011-06-01|2014-04-09|Hitachi, Ltd.|Battery system|
    CN103956902A|2007-06-15|2014-07-30|费希尔控制产品国际有限公司|Bidirectional DC to DC converter for power storage control in a power scavenging application|
    US20150061388A1|2012-01-04|2015-03-05|Juergen HAEFFNER|Method and device for monitoring a converter|
    CN104467073A|2009-12-04|2015-03-25|现代自动车株式会社|Method for controlling charging voltage of 12V auxiliary battery for hybrid vehicle|
    US20170158058A1|2015-12-03|2017-06-08|Hyundai Motor Company|Vehicle power control method and system for jump-start|
    US10014777B1|2017-08-09|2018-07-03|Texas Instruments Incorporated|Buck-boost DC-DC converter|
    US10211734B1|2018-07-17|2019-02-19|Huang-Jen Chiu|Bidirectional DC-DC converter|
    US10742021B1|2019-03-19|2020-08-11|Kabushiki Kaisha Toshiba|Power circuit, control method of power circuit, and self-driving device|US3105910A|1962-05-16|1963-10-01|Marshall R Chambers|Means for boosting run-down vehicle batteries|
    US4161023A|1977-09-07|1979-07-10|The United States Of America As Represented By The United States Department Of Energy|Up-and-down chopper circuit|
    US4736151A|1986-12-23|1988-04-05|Sundstrand Corporation|Bi-directional buck/boost DC/DC converter|
    US4801859A|1986-12-23|1989-01-31|Sundstrand Corporation|Boost/buck DC/DC converter|
    US5194799A|1991-03-11|1993-03-16|Battery Technologies Inc.|Booster battery assembly|
    US5162720A|1991-10-15|1992-11-10|Lambert Gordon K|Vehicle electrical system|
    US5488283A|1993-09-28|1996-01-30|Globe-Union, Inc.|Vehicle battery system providing battery back-up and opportunity charging|
    JPH0865904A|1994-06-06|1996-03-08|Nippondenso Co Ltd|Charger for electric automobile|
    US5852332A|1996-09-09|1998-12-22|Sheer Power Source, Inc.|Sheer power source|
    US5896022A|1996-12-13|1999-04-20|Jacobs, Sr.; John T.|Battery charge managing system|
    JPH1189002A|1997-09-09|1999-03-30|Matsushita Electric Ind Co Ltd|Vehicle|
    DE19813369B4|1998-03-26|2006-11-23|Robert Bosch Gmbh|Device for power supply in a motor vehicle|
    JPH11289676A|1998-04-01|1999-10-19|Toyo System Kk|Power unit for secondary battery charging and discharging device|
    US6125272A|1998-09-25|2000-09-26|Motorola, Inc.|Method and apparatus providing improved intermodulation distortion protection|
    DE19846319C1|1998-10-08|2000-02-17|Daimler Chrysler Ag|Energy supply circuit for automobile electrical network, uses multi-level controller with input/output terminals coupled to respective voltage supply paths for HV and LV loads and back-up storage battery|US6554088B2|1998-09-14|2003-04-29|Paice Corporation|Hybrid vehicles|
    DE19941699A1|1999-09-02|2001-03-08|Bosch Gmbh Robert|Semiconductor fuse for electrical consumers|
    DE19955721A1|1999-11-15|2001-05-17|Volkswagen Ag|Two-battery system|
    US6455951B1|2000-08-16|2002-09-24|Yazaki North America, Inc.|Auto charger for system including a high voltage supply and a low voltage supply|
    JP2004512798A|2000-10-27|2004-04-22|コーニンクレッカ フィリップス エレクトロニクス エヌ ヴィ|Converter control|
    JP2004518396A|2001-01-23|2004-06-17|コーニンクレッカ フィリップス エレクトロニクス エヌ ヴィ|Digitally controlled DC / DC converter|
    GB2373648A|2001-03-23|2002-09-25|Motorola Inc|DC-DC converter circuit for use in an automotive integrated starter-alternatorarrangement|
    DE10119985A1|2001-04-24|2002-10-31|Bosch Gmbh Robert|Device for feeding energy into a multi-voltage electrical system of a motor vehicle|
    TWI264172B|2001-08-29|2006-10-11|Oqo Inc|Bi-directional DC power conversion system|
    US6437462B1|2001-12-10|2002-08-20|Delphi Technologies, Inc.|Bi-directional DC/DC converter and control method therefor|
    US20030155894A1|2002-02-07|2003-08-21|International Rectifier Corporation|DC to DC converter with tapped inductor|
    US6653813B2|2002-03-21|2003-11-25|Thomson Licensing, S.A.|Apparatus and method for the power management of operatively connected modular devices|
    FR2838572B1|2002-04-12|2004-08-20|Valeo Equip Electr Moteur|CHARGING SYSTEM FOR AN ELECTRICAL ENERGY STORAGE DEVICE, SUCH AS A SUPER-CAPACITOR FROM A BATTERY AND PARTICULARLY A MOTOR VEHICLE, AND METHOD OF USING THE SAME|
    JP3556648B2|2002-07-08|2004-08-18|日本テキサス・インスツルメンツ株式会社|DC-DC converter and control circuit for DC-DC converter|
    US20040012368A1|2002-07-17|2004-01-22|Massey Paul G.|Method and apparatus for charging a rechargeable cell|
    EP1403143B1|2002-09-30|2007-01-03|Ford Global Technologies, LLC|Power supply procedur in a power network with a super-capacitor|
    DE10253276B4|2002-11-15|2005-05-04|Siemens Ag|Method and device for ensuring the specified voltage on a vehicle electrical system in motor vehicles|
    EP1437823B1|2003-01-08|2012-12-12|Continental Automotive GmbH|Wide input range, DC-DC voltage-switching converter regulator device with boost and buck modes|
    US7932634B2|2003-03-05|2011-04-26|The Gillette Company|Fuel cell hybrid power supply|
    DE10313752B4|2003-03-27|2021-06-24|Bayerische Motoren Werke Aktiengesellschaft|Device and method for charging batteries of a multi-voltage electrical system of a motor vehicle|
    DE10317380A1|2003-04-15|2004-11-18|Infineon Technologies Ag|Direct current -DC converter for converting a higher input voltage into a lower output voltage has a series connection for a choke and a capacitor|
    EP1508957A1|2003-08-22|2005-02-23|Alcatel|System for controlling the energy flow in an energy conversion system|
    DE10344563A1|2003-09-25|2005-04-28|Bosch Gmbh Robert|DC electrical system|
    JP4535492B2|2004-07-21|2010-09-01|株式会社京三製作所|Buck-boost chopper circuit|
    DE202005021974U1|2004-09-30|2012-01-19|Flexiva Automation & Robotik Gmbh|DC / DC converter module|
    US7363525B2|2004-10-07|2008-04-22|Cisco Technology, Inc.|Bidirectional inline power port|
    US7893665B2|2005-09-07|2011-02-22|Linear Technology Corporation|Peak charging current modulation for burst mode conversion|
    US7642743B1|2005-12-19|2010-01-05|Cooper Technologies Company|Charger for remote battery|
    GB0526625D0|2005-12-30|2006-02-08|Microgen Energy Ltd|Power supply|
    US7382113B2|2006-03-17|2008-06-03|Yuan Ze University|High-efficiency high-voltage difference ratio bi-directional converter|
    CA2558137A1|2006-04-04|2007-10-04|A.O. Smith Corporation|Electrical machine having a series chopper circuit|
    JP4449940B2|2006-05-16|2010-04-14|トヨタ自動車株式会社|Dual power supply system for vehicles|
    FR2903247B1|2006-06-29|2008-09-12|Valeo Equip Electr Moteur|METHOD AND DEVICE FOR CHARGING AN ELECTRIC ENERGY STORAGE MEMBER, IN PARTICULAR A ULTRAC-CAPACITOR|
    US7899415B1|2006-09-22|2011-03-01|Rockwell Collins, Inc.|Low-frequency power line emissions reduction system and method|
    ITTO20060690A1|2006-09-27|2008-03-28|Fiat Auto Spa|DEVICE FOR INTERCONNECTION AND CONTROL OF ELECTRICAL INSTALLATIONS OF A VEHICLE|
    US7764045B2|2006-10-05|2010-07-27|Eveready Battery Company, Inc.|Battery charger|
    US7750598B2|2006-10-05|2010-07-06|Eveready Battery Company, Inc.|Battery charger user interface|
    US20080286725A1|2007-05-14|2008-11-20|Jones Giles D|Electrical Power Converter for a Simulated Weapon Device|
    US8193784B2|2007-06-15|2012-06-05|Fisher Controls International Llc|Bidirectional DC to DC converter for power storage control in a power scavenging application|
    DE102007062955B4|2007-12-21|2011-06-01|Catem Develec Gmbh & Co. Kg|Circuit for voltage stabilization of a vehicle electrical system|
    US8358107B2|2007-12-31|2013-01-22|Intel Corporation|Bidirectional power management techniques|
    US8076797B2|2008-05-15|2011-12-13|Indy Power Systems Llc|Energy transfer circuit and method|
    JP4643695B2|2008-09-02|2011-03-02|日立コンピュータ機器株式会社|Bidirectional DC-DC converter and control method thereof|
    DE202009000099U1|2008-09-03|2009-04-23|Gigatronik Stuttgart Gmbh|Circuit arrangement with a battery coupler|
    WO2011014593A2|2009-07-31|2011-02-03|Thermo King Corporation|Bi-directional battery voltage converter|
    DE102009041006A1|2009-09-10|2011-03-24|Bayerische Motoren Werke Aktiengesellschaft|Motor vehicle power supply has two sub networks, which are electrically connected with one another by coupling element|
    DE102009057084A1|2009-12-04|2011-06-09|Continental Automotive Gmbh|Reverse polarity protection circuit for a motor vehicle electrical system and motor vehicle electrical system with a reverse polarity protection circuit|
    KR100997377B1|2010-01-05|2010-11-30|서울과학기술대학교 산학협력단|Bi-directional non-isolated dc-dc converter|
    DE102010001239A1|2010-01-27|2011-07-28|SB LiMotive Company Ltd., Kyonggi|Battery system for motor vehicles with high power consumers|
    US8552697B2|2010-02-02|2013-10-08|Cognipower, Llc|Universal single-stage power converter with PFC capability|
    US8981710B2|2010-09-20|2015-03-17|Indy Power Systems Llc|Energy management system|
    US8994349B2|2010-12-03|2015-03-31|The Boeing Company|Synchronous rectifier bi-directional converter|
    DE102011003565A1|2011-02-03|2012-08-09|Bayerische Motoren Werke Aktiengesellschaft|Foreign starter device for a motor vehicle|
    US8941264B2|2011-06-20|2015-01-27|Bae Systems Information And Electronic Systems Integration Inc.|Apparatus for bi-directional power switching in low voltage vehicle power distribution systems|
    US20140159478A1|2011-08-30|2014-06-12|Toyota Jidosha Kabushiki Kaisha|Power supply system for vehicle|
    US20130141070A1|2011-12-01|2013-06-06|Intersil Americas LLC|Control system and method for shared inductor regulator|
    US9360507B2|2011-12-19|2016-06-07|Tyco Safety Products Canada Ltd.|Displacement tamper sensor and method|
    US9711962B2|2012-07-09|2017-07-18|Davide Andrea|System and method for isolated DC to DC converter|
    JP6103874B2|2012-10-12|2017-03-29|株式会社日立情報通信エンジニアリング|Power supply device and its operation method|
    DE102012218914A1|2012-10-17|2014-04-17|Robert Bosch Gmbh|Protective circuit arrangement for a multi-voltage network|
    KR101355339B1|2012-10-30|2014-02-05|엘에스산전 주식회사|Apparatus and method for controlling bi-directional dc-dc converter|
    WO2014112608A1|2013-01-21|2014-07-24|Semiconductor Energy Laboratory Co., Ltd.|Secondary battery, secondary battery module, method for charging the secondary battery and the secondary battery module, method for discharging the secondary battery and the secondary battery module, method for operating the secondary battery and the secondary battery module, power storage system, and method for operating the power storage system|
    US9812949B2|2013-10-10|2017-11-07|Indy Power Systems Llc|Poly-phase inverter with independent phase control|
    JP6504906B2|2015-05-08|2019-04-24|本田技研工業株式会社|Fuel injection device for internal combustion engine|
    JP6278007B2|2015-07-14|2018-02-14|トヨタ自動車株式会社|Power system|
    US20170203666A1|2016-01-19|2017-07-20|Ford Global Technologies, Llc|Battery charging system and servicing method|
    US10199833B1|2016-03-04|2019-02-05|Seagate Technology Llc|Power balancing|
    法律状态:
    2000-12-20| AS| Assignment|Owner name: MOTOROLA, INC., ILLINOIS Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:MILLER, PETER;REEL/FRAME:011403/0454 Effective date: 20001213 |
    2005-03-29| FPAY| Fee payment|Year of fee payment: 4 |
    2006-10-31| AS| Assignment|Owner name: TEMIC AUTOMOTIVE OF NORTH AMERICA, INC., ILLINOIS Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:MOTOROLA, INC.;REEL/FRAME:018471/0200 Effective date: 20061016 |
    2009-03-26| FPAY| Fee payment|Year of fee payment: 8 |
    2013-06-28| REMI| Maintenance fee reminder mailed|
    2013-11-20| LAPS| Lapse for failure to pay maintenance fees|
    2013-12-16| STCH| Information on status: patent discontinuation|Free format text: PATENT EXPIRED DUE TO NONPAYMENT OF MAINTENANCE FEES UNDER 37 CFR 1.362 |
    2014-01-07| FP| Expired due to failure to pay maintenance fee|Effective date: 20131120 |
    优先权:
    申请号 | 申请日 | 专利标题
    GB992985.2||1999-12-20||
    GB9929895A|GB2357641B|1999-12-20|1999-12-20|DC-DC Converter and energy management system|
    GB9929895||1999-12-20||
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