Abstract:
An induced power system for being connected with and driving loads ( 300 ) includes a primary circuit ( 100 ) and a secondary circuit ( 200 ). The primary circuit ( 100 ) is provided with a primary inductor ( 110 ) for generating current induced magnetic filed. The secondary circuit ( 200 ) is provided with an induce generation portion ( 210 ) and a power distribution portion ( 220 ). The induce generation portion ( 210 ) is provided with a first inductor ( 211 ) and a second inductor ( 212 ) connected in series with each other and adjacent with the primary inductor ( 110 ), for generating induced alter current. The power distribution portion ( 220 ) is provided with a first capacitor ( 221 ), a second capacitor ( 222 ) and a switching device ( 225 ), in which the first capacitor ( 221 ) is connected with the first inductor ( 211 ) in series to generate series resonance, thus to provide a control power supply. The second capacitor ( 222 ) is connected with the first, the second inductors ( 211, 212 ) and the first capacitor ( 221 ) in parallel to generate parallel resonance, thus to provide a load power supply. When the switching device ( 225 ) is on, the load power supply is provided to the loads ( 300 ).

Description:
BACKGROUND OF THE INVENTION 
       [0001]    1. Field 
         [0002]    The present invention relates to an induction power system, and more particularly, to an induction power system with high power efficiency. 
         [0003]    2. Related Art 
         [0004]    An inductively coupled power transfer (ICPT) system is configured to effectively transfer energy of a primary side circuit with a stable power supply into a non-contact secondary side circuit a certain distance away through magnetic field induction. The technology has already been widely used in various applications, for example non-contact battery charging in an electric vehicle, cell phones, portable electronic devices, medical implants, as a non-contact power supply in a material handling device and/or system, and public transportation systems. The technology has advantages such as safety, stability, long service life, and easy maintenance. 
         [0005]    In an induction power system, the power supply efficiency is always one factor that needs to be enhanced and surmounted. Previously, the secondary side circuit is usually provided with one set of power to drive both the control circuit and load circuit of the system. As the control power and the load power are inseparable, a system standby function supplying power only to the control circuit but not the load circuit is usually unable to be provided. In such systems, when load power is not required at a no load condition, manually switching off the complete secondary side circuit wastes time, while maintaining the entire secondary side circuit wastes power. 
         [0006]    In an induction power system, the working frequency is another factor expected to be enhanced and surmounted in order to minimize the size of the system device and the manufacturing cost. However, it has previously been limited by the power loss that occurs due to current switching of its primary side circuit. 
       SUMMARY OF THE INVENTION 
       [0007]    The present invention is an induction power system consisting of a system standby function, increased power supply efficiency, reduced power loss due to current switching, increased system working frequency, and reduced manufacturing cost. 
         [0008]    Accordingly, the present invention provides an induction power system configured to connect and drive a load. The induction power system comprises a primary side circuit and a secondary side circuit. The primary side circuit comprises at least one main inductor configured to generate a current-induced magnetic field. The secondary side circuit comprises an induction electrification unit and a power distribution unit. The induction electrification unit comprises a first inductor and a second inductor, and the first inductor and the second inductor are electrically connected in series. The induction electrification unit is adjacent to the primary side circuit, and is configured to generate an induced alternating current (AC). The power distribution unit comprises a first capacitor and a second capacitor. The first capacitor and the first inductor are electrically connected in series, and the first capacitance value matches the first inductance value, so as to generate a series resonance and provide a control power. The second capacitor is electrically connected in parallel with the first capacitor, the first inductor, and the second inductor, and the second capacitance value matches the second inductance value, so as to generate a parallel resonance and provide a load power. 
         [0009]    The power distribution unit further comprises a transformer rectifier unit, a switching device, an AC/DC converter and a second control unit. One side of the transformer rectifier unit forms a loop with the first capacitor and the first inductor, such that the control power is converted into a direct current (DC) control power. The switching device is electrically connected to the second inductor in series. When the switching device is turned on, the power distribution unit provides the load power to the load, and when the switching device is turned off, the power distribution unit stops providing the load power. The AC/DC converter is connected in parallel with the second capacitor to convert the load power into a direct current (DC) load power. 
         [0010]    The secondary side circuit further comprises a first control unit. The first control unit is configured to accept the DC control power from the power distribution unit, and is able to turn on and turn off the switching device selectively to control the load power. 
         [0011]    In order to better achieve the objective, the present invention further provides another secondary side circuit comprising a plurality of induction electrification units and power distribution units, and a control unit. The control unit is configured to accept DC load powers gathered by the power distribution units, and the control unit is electrically connected to a load to control and drive the load. 
         [0012]    In addition, the present invention further provides another secondary side circuit comprising a plurality of induction electrification units and power distribution units, and a control unit. The DC load powers gathered by the power distribution units are configured to connect and drive a load. The DC control powers gathered by the power distribution units are connected to the control unit. The control unit is able to turn on and turn off the switches of the power distribution units to control the DC load powers to the load. 
         [0013]    The present invention further provides a primary side circuit. The primary side circuit comprises at least one main inductor, and is configured to generate a current-induced magnetic field, such that a secondary side circuit adjacent to the main inductor generates an induced AC. At the same time, the primary side circuit comprises an inverter, a matching inductor, and a main capacitor. The inverter, the matching inductor, the main capacitor, and the main inductor match each other, such that the inverter output consists of a discontinuous current. The inverter comprises a plurality of switches and a driver with a fixed switching frequency. Switching occurs when the discontinuous current is zero or when the discontinuous current flows through the inverse diode of the switch, in order to minimize switching loss. 
         [0014]    An effect of the present invention is that the proposed secondary side circuit is able to provide two sets of power at the same time by connecting a plurality of inductors and capacitors in series and in parallel. One set is a load power and provides power needed by the load. The other set is a control power. The control power is a small power configured to provide a power that maintains system standby and enables load power, thereby reducing waste of power at a no load condition, so as to achieve a higher efficiency. 
         [0015]    Another effect of the present invention is that the proposed secondary side circuit is able to provide a load power more than three times as large as that in the prior art, such that the efficiency is effectively enhanced. 
         [0016]    Another effect of the present invention is that the proposed secondary side circuit has a plurality of induction electrification units and power distribution units, so that it provides a larger power. 
         [0017]    Another effect of the present invention is that the proposed primary side circuit has a fixed working frequency, and its inverter is able to output a discontinuous current, such that a power loss resulting from current switching is effectively reduced. Therefore, the working frequency of the induction power system is practically increased, the size of the system device is decreased, and the manufacturing cost is reduced. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0018]    The present invention will become more fully understood from the detailed description given herein below for illustration only, and thus are not limitative of the present invention, and wherein: 
           [0019]      FIG. 1  is an architectural view of an induction power system according to a first embodiment of the present invention; 
           [0020]      FIG. 2A  is a circuit diagram of an inductor-capacitor (LC) parallel resonance in the prior art; 
           [0021]      FIG. 2B  is a circuit diagram of an inductor-capacitor (LC) serial-parallel resonance of the present invention; 
           [0022]      FIG. 3A  is an architectural view of an induction power system according to a second embodiment of the present invention; 
           [0023]      FIG. 3B  is an architectural view of an induction power system according to a third embodiment of the present invention; 
           [0024]      FIG. 4  is an architectural view of an induction power system according to a fourth embodiment of the present invention; 
           [0025]      FIG. 5  is an architectural view of an induction power system according to a fifth embodiment of the present invention; 
           [0026]      FIG. 6A  is a schematic view of terminal voltage changes according to the first embodiment of the present invention; 
           [0027]      FIG. 6B  is a schematic view of terminal voltage changes according to the fourth embodiment of the present invention; and 
           [0028]      FIG. 6C  is a schematic view of terminal voltage changes according to the fifth embodiment of the present invention. 
       
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       [0029]    The present invention is illustrated below in detail with reference to the embodiments. 
         [0030]    First,  FIG. 1  is an architectural view of an induction power system according to a first embodiment of the present invention. In the first embodiment of the present invention, the induction power system comprises a primary side circuit  100  and a secondary side circuit  200 , and is configured to connect and drive a load  300 . The primary side circuit  100  at least has a main inductor  110  configured to generate a current-induced magnetic field. 
         [0031]    The secondary side circuit  200  comprises an induction electrification unit  210 , a power distribution unit  220 , and a first control unit  241 . The induction electrification unit  210  is adjacent to the main inductor  110  of the primary side circuit  100 , and the induction electrification unit  210  comprises a first inductor  211  and a second inductor  212 . The first inductor  211  and the second inductor  212  are electrically connected in series. The first and second inductors  211 ,  212  are located in a range of the current-induced magnetic field generated by the main inductor  110  of the primary side circuit  100 , such that a corresponding induced AC is generated. 
         [0032]    The power distribution unit  220  comprises a first capacitor  221 , a second capacitor  222 , a switching device  225 , an AC/DC converter  228 , a second control unit  242 , and a transformer rectifier unit  226 . The first capacitor  221  and the first inductor  211  are electrically connected in series, and the capacitance value of the first capacitor  221  matches the inductance value of the first inductor  211  to generate a series resonance, thereby providing an AC control power (I CA ). 
         [0033]    At the same time, the second capacitor  222  is connected in parallel with the first inductor  211 , the second inductor  212 , and the first capacitor  221 , and the capacitance value of the second capacitor  222  matches the inductance value of the second inductor  212  to generate a parallel resonance, thereby providing an AC load power (I LA ). 
         [0034]    The power distribution unit  220  further has a transformer rectifier unit  226 . The transformer rectifier unit  226  comprises a transformer  2261 , a plurality of rectifier diodes  2262 , and a capacitor  2263 . One side of the transformer  2261  forms a loop with the first inductor  211  and the first capacitor  221 . The transformer  2261  provides functions of circuit isolation and voltage transformation, and the rectifier diodes  2262  and the capacitor  2263  convert the I CA  into a DC control power (I CD ). The I CD  may be conveyed and provided to the first control unit  241  and the second control unit  242 . 
         [0035]    The power distribution unit  220  further has an AC/DC converter  228  and a second control unit  242 . The AC/DC converter  228  converts the I LA  into a DC load power (I LD ) to drive and supply power to the load  300 . The second control unit  242  accepts the I CD ) and is electrically connected to the AC/DC converter  228  to control the I LD . 
         [0036]    The power distribution unit  220  further has a switching device  225 . The switching device  225  and the second inductor  212  are connected in series. Therefore, as shown in  FIG. 1 , the serial connection of the switching device  225  does not influence the operation of the loop formed of the first inductor  211  and the first capacitor  221 , that is, the control power (I CA  and I CD  may be generally referred to as a control power) is not influenced by the operation of the switching device  225 . However, when the switching device  225  is turned on, the power distribution unit  220  may provide the load power (I LA  and I LD  may be generally referred to as a load power), and when the switching device  225  is turned off, the power distribution unit stops providing the load power. 
         [0037]    The secondary side circuit  200  further has the first control unit  241 . The first control unit  241  is configured to accept the I CD  provided by the power distribution unit  220 , and is able to turn on and turn off the switching device  225  to control the load power. 
         [0038]    In conclusion, the secondary side circuit  200  may distribute the induced AC generated by the induction electrification unit  210  through the power distribution unit  220  into two sets of power, namely, the control power and the load power. The load power has main power of the system, and is configured to supply the power required by the load  300 . The control power has relatively small power, and is configured to be supplied to control systems of the first and second control units  241 ,  242 . During a system standby status, when load power is not required at a no load condition, the first control unit  241  may be used to control the switching device  225  to turn off the connection, so as to save the loss of the system main power, and to turn on the switching device  225  at any time, when power is required by the load. 
         [0039]    In addition to a main inductor  110 , the primary side circuit  100  further comprises a power supply input terminal  120 , a rectification circuit  130 , an inverter  140 , a matching inductor  150 , and a main capacitor  160 . The power supply input terminal  120  is configured to connect an external AC power supply, for example, an 110V, 220V or 380V AC power supply, to the rectification circuit  130 . The rectification circuit  130  converts the AC power supply into a DC power supply for the inverter  140 . The inverter  140  is formed of a plurality of switches  141  and a driver  142  with a fixed working frequency to transform the DC power supply into a high-frequency AC power supply. The inverter output is connected to the matching inductor  150 , the main capacitor  160  and the main inductor  110 . The main capacitor  160  and the main inductor  110  are electrically connected in parallel, and the capacitance value of the main capacitor  160  matches the inductance value of the main inductor  110  to generate a parallel resonance, thereby providing a current-induced magnetic field to enable the secondary side circuit  200 . At the same time, the inductance value of the matching inductor  150  matches the inverter output and the parallel resonance, such that the output current of the inverter  140  is discontinuous. The driver  142  is configured to turn on and turn off the switch  141  when the discontinuous current is zero, or when the discontinuous current passes through the inverse diode of the switch  141 , so as to minimize the switching losses. 
         [0040]    Next, referring to  FIG. 2A , in the prior art, when the inductor  21  and the capacitor  22  are connected in parallel to generate a resonance, it is equivalently a current source power supply with a first constant current (I 1 ), and the first constant current (I 1 ) is inversely proportional to the length L of the inductor  21 . Therefore, longer inductor  21  results in smaller first constant current (I 1 ). 
         [0041]    Subsequently, referring to  FIG. 2B , in the present invention, when the first inductor  211  and the first capacitor  221  are connected in series to generate a series resonance, and the first inductor  211 , the second inductor  212 , and the first capacitor  221  are connected in parallel with the second capacitor  222  to generate a parallel resonance, it is equivalently a current source power supply with a second constant current (I 2 ), and the second constant current (I 2 ) is inversely proportional to a length of the second inductor  212 . In the embodiment, a length of the second inductor  212  is ⅓ L, and a length of the first inductor  211  is ⅔ L. As the length of the second inductor  212  is only ⅓ L, in the present invention, the second constant current (I 2 ) is three times as large as the first constant current (I 1 ) in the prior art. Therefore, the total output power is also three times as large as that in the prior art. 
         [0042]    Of course, the total output power in the present invention is not limited to merely three times as large as that in the prior art. Its amplification ratio may be determined by adjusting a ratio between lengths of the first inductor  211  and the second inductor  212 . For example, in the circuit, if a length L 2  of the second inductor  212  is ⅕ L, and the total output power may be five times as large as that in the prior art. 
         [0043]      FIG. 3A  is an architectural view of an induction power system according to a second embodiment of the present invention. In the second embodiment of the present invention, the secondary side circuit  200  of the induction power system comprises a plurality of induction electrification units  210  and a plurality of power distribution units  220 . The plurality of induction electrification units  210  is all adjacent to the main inductor  110  of the primary side circuit  100 . The DC load power gathered by the plurality of power distribution units  220  is conveyed to the control unit  240 . The control unit  240  drives and supplies power to the load  300 . 
         [0044]      FIG. 3B  is an architectural view of an induction power system according to a third embodiment of the present invention. In the third embodiment of the present invention, the secondary side circuit  200  of the induction power system also comprises a plurality of induction electrification units  210  and a plurality of power distribution units  220 , and the plurality of induction electrification units  210  are all adjacent to the main inductor  110  of the primary side circuit  100 . The DC control power I CD  gathered by each power distribution unit  220  is conveyed to the control unit  240 , and the DC load power I LD  gathered by each power distribution unit  220  is conveyed to the load  300 . In addition, the control unit  240  is able to turn on or turn off a switching device (not shown) in each power distribution unit  220 , respectively, thereby controlling the load power to the load  300 . 
         [0045]      FIG. 4  is an architectural view of an induction power system according to a fourth embodiment of the present invention. In the fourth embodiment of the present invention, the first capacitor  221  is disposed between the first inductor  211  and the second inductor  212 , and they are electrically connected in series as in the first embodiment. 
         [0046]      FIG. 5  is an architectural view of an induction power system according to a fifth embodiment of the present invention. In the fifth embodiment of the present invention, the secondary side circuit  200  further comprises a third inductor  213 , and a third capacitor  223 . The first inductor  211 , the first capacitor  221 , the third inductor  213 , and the third capacitor  223  are electrically connected in series, and form a loop with one side of the transformer  2261 . The inductance values of the first inductor  211  and the third inductor  213  matches the capacitance values of the first capacitor  221  and the third capacitor  223 , respectively, to generate a series resonance, and thereby providing a control power. The second capacitor  222  is electrically connected in parallel with the first inductor  211 , the first capacitor  221 , the third inductor  213 , the third capacitor  223 , and the second inductor  212 . The inductance value of the second inductor  212  matches the value of the second capacitor  222  to generate a parallel resonance, and thereby providing a load power. 
         [0047]    Referring to  FIGS. 1 ,  4 ,  5 ,  6 A,  6 B, and  6 C, in the first embodiment, the first inductor  211  resonates with the first capacitor  221 , such that the terminal voltage (Vac) of the first capacitor  221  and the terminal voltage (Vcb) of the first inductor  211  have relatively large values. The terminal voltage (Vcb) of the first inductor  211  further comprises two parts. The first part is a terminal voltage that resonates with the first capacitor  221 , which has the same size and an inverse phase. The second part is an induction electrification voltage enabled by the main inductor  110  of the primary side circuit  100 , and is a constant voltage (Vab). In the first embodiment, formulae of the terminal voltage vector are as follows. 
         [0000]    
       
      
       Vac=Va−Vc  
      
     
         [0000]    
       
      
       Vcb=Vc−Vb  
      
     
         [0000]    
       
      
       Vab=Va−Vb=Vac+Vcb  
      
     
         [0000]        Vbd=Vb−Vd= 0.5  Vcb    
         [0000]    
       
      
       Vcd=Vc−Vd=Vcb+Vbd  
      
     
         [0048]    In the fourth embodiment, the terminal voltage of each component is the same as that in the first embodiment. However, in the fourth embodiment, the first capacitor  221  is located between the first inductor  211  and the second inductor  212 , thus having an accumulated terminal voltage (Vcd) with a smaller value than that in the first embodiment. Also, the same constant voltage (Vab) is generated. In the fourth embodiment, formulae of the terminal voltage vector are as follows. 
         [0000]    
       
      
       Vae=Va−Ve  
      
     
         [0000]    
       
      
       Veb=Ve−Vb  
      
     
         [0000]    
       
      
       Vab=Va−Vb=Vae+Veb  
      
     
         [0000]        Vbd=Vb−Vd= 0.5  Vae    
         [0000]    
       
      
       Vcd=Vc−Vd=Vab+Vbd  
      
     
         [0049]    In the fifth embodiment, the first inductor  211  and the third inductor  213  resonates with the first capacitor  221  and the third capacitor  223  respectively, so the terminal voltage Vaf, Vfg, Vge, Veb of each component only has a smaller value being one half of that in the first embodiment. Also, the same constant voltage (Vab) is generated. In the fifth embodiment, formulae of the terminal voltage vector are as follows. 
         [0000]    
       
      
       Vaf=Va−Vf  
      
     
         [0000]    
       
      
       Vfg=Vf−Vg  
      
     
         [0000]    
       
      
       Vge=Vg−Ve  
      
     
         [0000]    
       
      
       Veb=Ve−Vb  
      
     
         [0000]    
       
      
       Vab=Va−Vb=Vaf+Vfg+Vge+Veb  
      
     
         [0000]    
       
      
       Vbd=Vb−Vd=Vaf=Vge  
      
     
         [0000]    
       
      
       Vcd=Vc−Vd=Vab+Vbd  
      
     
         [0050]    Of course, reduction of the terminal voltages of the series resonant inductor and capacitor components of the secondary side circuit is not limited to one half of that in the first embodiment. The reduction ratio is able to be determined by adjusting the number of the series resonant inductor and capacitor components. For example, if another inductor and another capacitor are further added such that the circuit has three equivalent inductors and three equivalent capacitors, and the inductors and capacitors are electrically connected in series in an “inductor-capacitor-inductor-capacitor-inductor-capacitor” sequence with inductance values and capacitance values matching each other in sequence to generate a series resonance, the terminal voltage of each component is able to be reduced to one third of that in the first embodiment. 
         [0051]    As can be seen from the above, in the fifth embodiment of the present invention, the secondary side circuit is able to avoid component damages caused by an instant high voltage resulting from resonance in the LC resonance circuit, and to avoid cost increase resulting from using higher voltage rating components, and to meet voltage regulations of different countries. 
         [0052]    The effect of the present invention is such that in the proposed induction power system, as a plurality of inductors and capacitors are connected in series and in parallel in the secondary side circuit, the system is able to provide two sets of powers. One set is a load power, which is a main power, and is configured to provide a power required by a load. The other set is a control power, which is a small power, and is configured to provide a power required to maintain system standby and enable a load power. Therefore, system power waste may be reduced. At the same time, the present invention further provides a secondary side circuit having a plurality of induction electrification units and power distribution units, so as to provide a larger power to the load. At the same time, the secondary side circuit of the present invention may practically provide a power more than three times as large as that in the prior art, such that the power supply efficiency is effectively enhanced.