JP6654535B2 - Load drive - Google Patents

Description

  The present invention relates to a load driving device.

  For example, Japanese Patent Application Laid-Open No. 2000-60027 (Patent Document 1) discloses a battery power compensating device that compensates for a battery mounted on a vehicle, a small boat, or the like to extremely lower the voltage due to a change in load or the like. There is technology. Patent Literature 1 states, “In a device in which a battery 13 is connected to a load 11 by a cable 13 and a compensation capacitor 12 is inserted on the input side of the load 11, a fluctuation of an input voltage to the load 11 is detected. A voltage detection circuit 27, a comparison circuit 28 for comparing a detected value with a reference value, a switch circuit 25 controlled by a comparison output, and an auxiliary capacitor 26 connected in parallel to the compensation capacitor 12 by the switch circuit 25. With this configuration, it is possible to provide a battery power compensator that can sufficiently suppress a voltage drop with a relatively simple circuit configuration.A display circuit that displays voltage fluctuations in multiple stages By adding No. 29, the effect of suppressing multi-level voltage fluctuation can be visually recognized. "

JP 2000-60027 A

  A conventional load drive device equipped with an in-vehicle ECU (Electronic Control Unit) uses a capacitor of several hundred μF (for example, the compensating capacitor 12 of Patent Document 1 described above).

  FIG. 20 is an explanatory diagram of a conventional load drive device 1 equipped with an in-vehicle ECU. FIG. 20A shows a block diagram of the load driving device 1. Loads 2 and 3 such as a microcomputer and a sensor are driven at 5V and 3.3V, respectively. Since the voltage (BATT) of the battery 8 is as high as 13.5 V, the step-down power supply 4 and the input circuit 7 are provided between the battery 8 and the loads 2 and 3. The step-down power supply 4 is a circuit for converting a high voltage to a low voltage. The input circuit 7 includes a diode 5 (D) and an input capacitor 6 (C1). The role of the input circuit 7 is as follows.

  The battery 8 is also connected to an inductive load 9 such as a solenoid and an injector. At the time of switching between conduction and disconnection of the inductive load 9, a period in which BATT becomes a negative voltage due to inductance back electromotive force occurs. The diode 5 (D) is for preventing a current from flowing backward from the loads 2 and 3 to the BATT when the BATT drops. Further, since it is necessary to drive the loads 2 and 3 even during the BATT lowering period, the input capacitor 6 (C1) is connected to the input terminal of the step-down power supply 4. This is because the loads 2 and 3 are driven by the energy stored in the input capacitor 6 (C1) during the BATT lowering period.

  The discharging operation of the input capacitor 6 (C1) is shown in FIG. During the period during which BATT decreases, the input capacitor 6 (C1) discharges, and the input voltage (VB) of the step-down power supply 4 decreases from the initial voltage (VB_initial). The lower limit (VB_min) of the input voltage (VB) of the step-down power supply 4 is the lower limit of the input voltage at which the step-down power supply 4 can generate 5 V and 3.3 V, and is determined by the maximum value of the load current and the power supply efficiency. VB_initial is a difference voltage between the normal voltage (13.5 V) of BATT and the forward voltage (VD) of the diode 5 (D). The capacitance value of the input capacitor 6 (C1) is determined by the maximum load current (Imax) of each of the loads 2 and 3, the efficiency (E) of the step-down power supply 4, and the maximum drop period (Tmax) of BATT, and is obtained from equation (1). Can be When the required capacitance value of the input capacitor 6 (C1) is obtained using the following numerical values, it is about 440 uF.

  Here, VB_min = 7V, VB_initial = 12.5V, Imax = 1A, Tmax = 2ms, E = 70%, Vo1 = 5V, Vo2 = 3.3V.

  A problem with the conventional load driving device as described above is that the capacitance value of the used capacitor is large.

  2. Description of the Related Art Technology for packaging an ECU1 (1 pkg ECU) for reducing the cost of a vehicle-mounted ECU has been developed. One issue for that is the elimination of electrolytic capacitors. Since the electrolytic capacitor contains an electrolytic solution inside, if the resin is sealed at a high temperature for 1 pkg ECU, the electrolytic solution evaporates. As a result, the function of the capacitor may be lost. On the other hand, if the electrolytic capacitor is simply replaced with a ceramic capacitor, since the capacity per ceramic capacitor is smaller than the electrolytic capacitor, a large number of capacitors must be arranged in parallel, and the mounting area of the 1 kg ECU increases. For example, in the case of a ceramic capacitor having a DC 50 V withstand voltage, the maximum capacitance value is only 10 uF. Therefore, it is necessary to reduce the capacitance value of the capacitor used in the ECU as much as possible.

  SUMMARY OF THE INVENTION It is an object of the present invention to provide a load driving device that loads a microcomputer or the like using a small-capacity capacitor in a vehicle-mounted ECU.

The outline of a typical embodiment disclosed in the present application will be briefly described as follows. That is, a first capacitance connected to the first wiring, a second capacitance connected to the second wiring, and a power supply for charging the first capacitance are connected to boost the voltage of the power supply. A first booster circuit that generates a voltage to be applied to the second wiring, and passes a current from the second wiring to the first wiring when the voltage of the first wiring decreases. possess a connection portion for the said first wiring is connected to the power supply via the first booster circuit, wherein the connecting portion of the first booster circuit and said first wiring A first switch element for switching between connection and disconnection, and a second switch element for switching between connection and disconnection between the first booster circuit and the second wiring, wherein the first booster circuit includes a coil , A second diode and a third switch element, one end of the coil The other end is connected to the anode of the second diode and the third switch element, and the cathode of the second diode is connected to the first switch element and the second switch element. The one end of the third switch element is connected to the anode of the second diode, the other end is connected to ground, and when the voltage of the first wiring is higher than a first threshold value, When the switch element is set to an on state, the second switch element and the third switch element are set to an off state, and the voltage of the first wiring decreases to the first threshold, the second switch element Is turned on, and when the voltage of the second wiring drops to a fifth threshold, the voltage of the first wiring and the voltage of the second wiring are boosted to the same value, 1 Sui Switch element, the second switch element, and the third switch element perform a switching operation, the voltage of the power supply rises to a second threshold, and the voltage of the second wiring is higher than a third threshold. When the voltage is low, the first switch element, the second switch element, and the third switch element perform a switching operation so as to increase the voltage of the second wiring to a value higher than the voltage of the first wiring. And when the voltage of the second wiring rises to a fourth threshold higher than the third threshold, the first switch element is turned on, and the second switch element and the third switch element are turned on. Is set to an off state .

  New features of the present embodiment will be apparent from the description of this specification and the accompanying drawings.

  According to one embodiment of the present invention, when the battery voltage drops, the load is driven by an auxiliary capacitor having a higher voltage than the normal voltage of the battery voltage, so that the total capacitance value of the auxiliary capacitor and the capacitor is smaller than that of the conventional input capacitor. Can be smaller. Problems, configurations, and effects other than those described above will be apparent from the following description of the embodiments.

1 is a block diagram illustrating a configuration of a load driving device according to a first embodiment of the present invention. FIG. 2 is an explanatory diagram illustrating an example of a booster circuit according to the first embodiment of the present invention. FIG. 2 is an explanatory diagram illustrating an example of a circuit of the BATT monitor according to the first embodiment of the present invention. FIG. 2 is an explanatory diagram illustrating an example of a VB monitor circuit according to the first embodiment of the present invention. FIG. 2 is an explanatory diagram illustrating an example of a circuit of a Vbis monitor according to the first embodiment of the present invention. FIG. 3 is an explanatory diagram illustrating an example of a boost controller according to the first embodiment of the present invention. FIG. 2 is an explanatory diagram illustrating an example of a capacitance connection controller according to the first embodiment of the present invention. 4 is a timing chart illustrating an operation of the load driving device according to the first exemplary embodiment of the present invention. 4 is a flowchart illustrating an operation of the load driving device according to the first exemplary embodiment of the present invention. FIG. 6 is a block diagram illustrating a configuration of a load driving device according to a second embodiment of the present invention. 6 is a timing chart illustrating an operation of the load driving device according to the second exemplary embodiment of the present invention. 6 is a flowchart illustrating an operation of the load driving device according to the second exemplary embodiment of the present invention. FIG. 9 is a block diagram illustrating a configuration of a load driving device according to a third embodiment of the present invention. FIG. 11 is an explanatory diagram illustrating an example of a booster circuit according to a third embodiment of the present invention. 9 is a timing chart illustrating an operation of the load driving device according to the third embodiment of the present invention. 9 is a flowchart illustrating an operation of the load driving device according to the third embodiment of the present invention. FIG. 13 is a block diagram illustrating a configuration of a load driving device according to a fourth embodiment of the present invention. 9 is a timing chart illustrating an operation of the load driving device according to the fourth embodiment of the present invention. 9 is a flowchart illustrating an operation of the load driving device according to the fourth embodiment of the present invention. FIG. 4 is an explanatory diagram of a conventional load drive device mounted on an in-vehicle ECU.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a block diagram illustrating a configuration of the load driving device 11 according to the first embodiment of the present invention.

  Among the components of the load driving device 11 shown in FIG. 1, the same components as those shown in FIG. 20 are denoted by the same reference numerals.

  The battery 8, the diode 5 (D), the load 2, and the load 3 of the first embodiment are the same as those in FIG.

  The load driving device 11 includes an input circuit 41 and a step-down power supply 12.

  The step-down power supply 12 is a circuit that converts a high voltage to a low voltage. The difference between the step-down power supply 12 and the step-down power supply 4 in FIG. 20A is that the voltage range of the input voltage VB that can be input to the step-down power supply 12 is wider than that of the step-down power supply 4, A response is possible (ie, higher values of VB can be converted to desired voltages (eg, 5V and 3.3V) and applied to loads 2 and 3).

  The input circuit 41 includes a diode 5 (D), a booster circuit 14, a Vbis monitor 18, a boost controller 17, an auxiliary capacitor 40 (Cbis), a capacitor 39 (C2), a VB monitor 15, a BATT monitor 19, a capacity connection unit 13, It is composed of a capacitance connection controller 16.

  The booster circuit 14 is a circuit that converts a low voltage to a high voltage.

  In the present embodiment, the entirety of the load driving device 11 is integrally resin-sealed.

  FIG. 2 is an explanatory diagram illustrating an example of the booster circuit 14 according to the first embodiment of the present invention.

  The booster circuit 14 of the present embodiment is, for example, a Dickson type charge pump including diodes 60 to 62, booster capacitors 63 to 64, and a phase inverting circuit 65. The booster circuit 14 is a circuit that boosts the voltage (BATT) of the battery 8 three times by the control signal (CP_C) and outputs the boosted voltage as an output voltage (Vbis). The multiple of boosting can be adjusted by adjusting the number of diodes and boosting capacitors. The greater the number of diodes and boost capacitors, the higher the multiple of boost.

  The BATT monitor 19 is a circuit that determines the voltage level of the battery voltage (BATT) based on the threshold value 2 and generates a determination signal (BATT_C).

  FIG. 3 is an explanatory diagram illustrating an example of a circuit of the BATT monitor 19 according to the first embodiment of the present invention.

  The BATT monitor 19 includes a comparator 26, an input terminal 27, an output terminal 29, and a reference voltage 28 (Vref1). When the battery voltage (BATT) is input to the input terminal 27, the BATT monitor 19 compares the battery voltage (BATT) with the reference voltage 28 (Vref1). When the battery voltage (BATT) falls below the reference voltage 28 (Vref1), the BATT monitor 19 outputs “L”. A determination signal (BATT_C) of “H” is generated, and when it rises from the reference voltage 28 (Vref1), a determination signal (BATT_C) of “H” is generated, and the generated determination signal (BATT_C) is output from the output terminal 29. The reference voltage 28 (Vref1) becomes the threshold value 2.

  The VB monitor 15 is a circuit that determines the voltage level of the input voltage (VB) of the step-down power supply 12 based on the threshold 1 and generates a determination signal (VB_C).

  FIG. 4 is an explanatory diagram illustrating an example of a circuit of the VB monitor 15 according to the first embodiment of the present invention.

  The VB monitor 15 includes a comparator 31, an input terminal 30, an output terminal 33, and a reference voltage 32 (Vref2). When the input voltage (VB) of the step-down power supply 12 is input to the input terminal 30, the VB monitor 15 compares the input voltage (VB) with the reference voltage 32 (Vref2). If the input voltage (VB) drops below the reference voltage 32 (Vref2), An "L" determination signal (VB_C) is generated, and when it rises above the reference voltage 32 (Vref2), an "H" determination signal (VB_C) is generated and the generated determination signal (VB_C) is output from the output terminal 33. . The reference voltage 32 (Vref2) becomes the threshold value 1.

  The Vbis monitor 18 is a circuit that determines the voltage level of the output voltage (Vbis) of the booster circuit 14 based on the thresholds 3 and 4, and generates a determination signal (Vbis_C).

  FIG. 5 is an explanatory diagram illustrating an example of a circuit of the Vbis monitor 18 according to the first embodiment of the present invention.

  The Vbis monitor 18 includes a resistor 23 (R1), a resistor 24 (R2), a hysteresis controller 22, an input terminal 20, an output terminal 21, and a reference voltage 25 (Vref3). When the output voltage (Vbis) of the booster circuit 14 is input to the input terminal 20, the Vbis monitor 18 compares the output voltage (Vbis) with the thresholds 3 and 4. When the output voltage (Vbis) rises above the threshold 3, the determination signal of “L” is output. (Vbis_C) is generated, and when it is lower than the threshold value 4, a determination signal (Vbis_C) of “H” is generated, and the generated determination signal (Vbis_C) is output from the output terminal 21. The thresholds 3 and 4 can be adjusted by the resistance 23 (R1), the resistance 24 (R2), and the reference voltage 25 (Vref3).

  The boost controller 17 controls the start or stop of the boost operation of the boost circuit 14 by the determination signal (BATT_C) from the BATT monitor 19, and controls the boost circuit 14 by the determination signal (Vbis_C) from the Vbis monitor 18. This circuit generates a control signal (CP_C) for controlling the voltage level of the output voltage (Vbis).

  FIG. 6 is an explanatory diagram illustrating an example of the boost controller 17 according to the first embodiment of the present invention.

  The boost controller 17 includes an input terminal 43, an input terminal 44, an output terminal 45, and a logical product 42. The boost controller 17 receives the determination signal (BATT_C) from the BATT monitor 19 at an input terminal 43, receives the determination signal (Vbis_C) from the Vbis monitor 18 at an input terminal 44 of the boost controller 17, and outputs a determination signal ( When “BATT_C” is “H”, the center value of the output voltage (Vbis) of the booster circuit 14 becomes the reference voltage 25 (Vref3) according to the determination signal (Vbis_C), and the ripple range of the output voltage (Vbis) from the threshold 3 A control signal (CP_C) is generated so as to be in a voltage range up to the threshold value 4, and the generated control signal (CP_C) is output from the output terminal 45. On the other hand, when the determination signal (BATT_C) is “L”, the boost controller 17 generates a control signal (CP_C) so as to stop the boost operation of the boost circuit 14 and outputs the control signal (CP_C) from the output terminal 45.

  The capacitance connection unit 13 is a circuit that connects or disconnects the auxiliary capacitor 40 (Cbis) and the capacitor 39 (C2) in parallel.

  The capacitance connection controller 16 generates a control signal (SW_C) for controlling connection or disconnection of the capacitance connection unit 13 based on the determination signal (VB_C) from the VB monitor 15 and the determination signal (BATT_C) from the BATT monitor 19. It is a circuit to generate.

  FIG. 7 is an explanatory diagram illustrating an example of the capacitance connection controller 16 according to the first embodiment of the present invention.

  The capacitance connection controller 16 includes an input terminal 34, an input terminal 35, an output terminal 38, a NAND 36, a NAND 37, and a logical NOT 46. The determination signal (VB_C) from the VB monitor 15 is input to the input terminal 34, and the determination signal (BATT_C) from the BATT monitor 19 is input to the input terminal 35. The capacitance connection controller 16 generates an “H” control signal (SW_C) at the falling edge of the determination signal (VB_C) from the VB monitor 15 and outputs the control signal (SW_C) from the output terminal 38. Further, the capacitance connection controller 16 generates a “L” control signal (SW_C) at the rising edge of the determination signal (BATT_C) from the BATT monitor 19 and outputs the control signal (SW_C) from the output terminal 38. The output terminal 38 is connected to the capacitance connection unit 13. When the control signal (SW_C) of “H” is input from the output terminal 38, the capacitance connection unit 13 is connected, and the auxiliary capacitor 40 (Cbis) and the capacitor 39 (C2) are connected in parallel. On the other hand, when the control signal (SW_C) of “L” is input, the capacitance connection unit 13 is turned off, and the connection between the auxiliary capacitor 40 (Cbis) and the capacitor 39 (C2) is cut off.

  The auxiliary capacitor 40 (Cbis) is a capacitor for storing energy for driving the loads 2 and 3 when the voltage (BATT) of the battery 8 decreases.

  The capacitor 39 (C2) is a capacitor for reducing noise such as switching noise.

  The input circuit 41 has the following role.

  (1) When the voltage (BATT) of the battery 8 decreases, the auxiliary capacitor 40 (Cbis) having a voltage (Vbis) higher than the normal voltage of the voltage (BATT) of the battery 8 drives the loads 2 and 3, so that The total capacitance value of the capacitor 40 (Cbis) and the capacitor 39 (C2) can be made smaller than that of the conventional input capacitor 6 (C1).

  (2) When the voltage (BATT) of the battery 8 is normal and the auxiliary capacitor 40 (Cbis) needs to be charged, the voltage (BATT) of the battery 8 is increased via the booster circuit 14 to the auxiliary capacitor 40 (Cbis). Are driven while the loads 2 and 3 are charged. When the voltage (BATT) of the battery 8 is normal and it is not necessary to charge the auxiliary capacitor 40 (Cbis), the booster circuit 14 stops operating, and the voltage (BATT) of the battery 8 Drive.

  In order to realize the above role, the operation mode of the input circuit 41 is set to one of the three modes shown in Table 1 below.

  FIG. 8 is a timing chart illustrating the operation of the load driving device 11 according to the first embodiment of the present invention.

  FIG. 9 is a flowchart illustrating the operation of the load driving device 11 according to the first embodiment of the present invention.

  The operation mode of the input circuit 41 will be described with reference to FIGS.

・ Normal mode → Cbis discharge mode:
In the normal mode (S901), when the voltage (BATT) of the battery 8 decreases, the capacitor 39 (C2) drives the loads 2 and 3, and the input voltage (VB) of the step-down power supply 12 is discharged by discharging the capacitor 39 (C2). ) Decreases. When the VB monitor 15 detects that the input voltage (VB) has dropped below the threshold 1 (S902: Yes), the input circuit 41 is set to the Cbis discharge mode (S903). That is, the capacitance connection unit 13 is connected, and the loads 2 and 3 are driven using the energy stored in the auxiliary capacitor 40 (Cbis).

  If the input voltage (VB) has not fallen below the threshold 1 (S902: No) and the voltage (BATT) of the battery 8 has not exceeded the threshold 2 (S908: No), the normal mode is set. It is continued (S901). The input voltage (VB) does not drop below the threshold 1 (S902: No), the voltage (BATT) of the battery 8 exceeds the threshold 2 (S908: Yes), and the voltage (Vbis) of the auxiliary capacitor 40 (Cbis). ) Exceeds the threshold value 3 (S909: Yes), the input circuit 41 is set to the Cbis charging mode (S906). The input voltage (VB) does not drop below the threshold 1 (S902: No), the voltage (BATT) of the battery 8 exceeds the threshold 2 (S908: Yes), and the voltage (Vbis) of the auxiliary capacitor 40 (Cbis). ) Does not exceed the threshold value 3 (S909: No), the normal mode is continued (S901).

-Cbis discharging mode → Cbis charging mode:
When the Vbis monitor 18 and the BATT monitor 19 detect that the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) has dropped below the threshold 3 and the voltage of the battery 8 (BATT) has risen above the threshold 2 (S904: Yes and S905: Yes), the input circuit 41 is set to the Cbis charging mode (S906). That is, the capacitor connection unit 13 is turned off, and the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) is boosted by the booster circuit 14 while the voltage (BATT) of the battery 8 drives the loads 2 and 3. That is, the auxiliary capacitor 40 (Cbis) is charged with the voltage boosted by the booster circuit 14.

・ Cbis discharge mode → normal mode:
When the Vbis monitor 18 and the BATT monitor 19 detect that the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) is higher than the threshold 3 and the voltage of the battery 8 (BATT) is higher than the threshold 2 (S904: Yes and (S905: No), the input circuit 41 is set to the normal mode (S901). That is, the capacity connection unit 13 is turned off, and the battery 8 (BATT) drives the loads 2 and 3.

・ Cbis charging mode → normal mode:
When the Vbis monitor 18 detects that the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) has risen above the threshold value 4 (S907: Yes), the input circuit 41 is set to the normal mode (S901). That is, the boosting circuit 14 stops the boosting operation, and the battery 8 drives the loads 2 and 3.

  The thresholds 1 to 4 are set as shown in Table 2 below. In the example of FIG. 8, threshold values 1 to 4 are set to 7V, 7.5V, 30V and 32V, respectively.

  As described above, when the input circuit 41 of the load driving device 11 according to the first embodiment is used, when the voltage (BATT) of the battery 8 decreases, the voltage (Vbis) higher than the normal voltage of the voltage (BATT) of the battery 8 is used. ), The loads 2 and 3 are driven by the auxiliary capacitor 40 (Cbis), so that the total capacitance of the auxiliary capacitor 40 (Cbis) and the capacitor 39 (C2) can be smaller than that of the conventional input capacitor 6 (C1). As the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) is higher, the total capacitance value of the auxiliary capacitor 40 (Cbis) and the capacitor 39 (C2) can be reduced. This is because the higher the voltage of the capacitor, the more charge can be accumulated. Specifically, it is desirable that Vbis be sufficiently larger than VB such that the charge amount Q2 (= Cbis × Vbis) of the auxiliary capacitor 40 is larger than the charge amount Q1 (= C2 × VB) of the capacitor 39. Therefore, for example, it is desirable that the threshold value 4 is a value equal to or greater than the value of Vbis that satisfies Cbis × Vbis> C2 × VB. As a result, a ceramic capacitor is employed as the auxiliary capacitor 40 (Cbis) and the capacitor 39 (C2), and the entire load driving device 11 (or the entire ECU including the load driving device 11) is resin-sealed to form one package. Thereby, cost reduction can be realized.

  The capacitance connection unit 13 of the input circuit 41 of the load driving device 11 according to the first embodiment may use a MOSFET (Metal Oxide Semiconductor Field Effect Transistor) or a bipolar transistor, or may use a circuit having a step-down function. . As a result, connection and disconnection between the auxiliary capacitor 40 (Cbis) to which a sufficient voltage satisfying the above conditions is applied and the capacitor 39 (C2) can be switched as necessary. When the capacitance connection unit 13 is a MOSFET, for example, immediately after the capacitance connection unit 13 enters the connection state, the charge stored in the auxiliary capacitor 40 (Cbis) passes through the capacitance connection unit 13 and passes through the capacitor 39 (C2). ), It is assumed that VB rises more than a normal value (for example, about 12 V). For this reason, it is necessary to use a step-down power supply 12 that can cope with high VB. On the other hand, when the capacitor connection unit 13 includes a circuit having a step-down function, Vbis, which is significantly higher than the normal value of VB, is stepped down to a desired voltage (for example, a voltage approximately equal to VB in the normal state), so that the capacitor connection is reduced. It is possible to suppress a significant increase in VB when the unit 13 is in the connected state.

  Next, a second embodiment of the present invention will be described. Except for differences described below, each unit of the system according to the second embodiment has the same function as each unit denoted by the same reference numeral in the first embodiment illustrated in FIGS. 1 to 9. Is omitted.

  In the case of the first embodiment, a VB monitor 15 and a capacitance connection controller 16 are required to control the capacitance connection unit 13. This complicates the control circuit. Further, since the voltage level (Vbis) of the auxiliary capacitor 40 (Cbis) becomes higher than the VB voltage, it is necessary to replace the step-down power supply 4 with the step-down power supply 12. On the other hand, a second embodiment has been proposed in order to simplify the control circuit and use the step-down power supply 4 as it is.

  FIG. 10 is a block diagram illustrating the configuration of the load driving device 49 according to the second embodiment of the present invention. The same components in FIGS. 10, 1 and 20 are denoted by the same reference numerals.

  The battery 8, the load 2, and the load 3 of the second embodiment are the same as those shown in FIG. 1, and the step-down power supply 4 is the same as that shown in FIG.

  The load driving device 49 includes an input circuit 48 and the step-down power supply 4.

  The diode 5 (D) and the capacitor C2 of the input circuit 48 are the same as those shown in FIG.

  The input circuit 48 includes a diode 5 (D), a booster circuit 50, a Vbis monitor 52, a boost controller 53, a capacitor 51 (Cbis1), a capacitor 39 (C2), a BATT monitor 54, and a diode 47.

  The booster circuit 50 is a circuit that converts a low voltage to a high voltage. The difference between the booster circuit 50 and the booster circuit 14 of FIG. 1 is that the booster circuit 50 can generate a positive output voltage Vbis from a negative input voltage BATT.

  The BATT monitor 54 is a circuit that determines the voltage level of the battery voltage (BATT) based on the threshold 5 and generates a determination signal (BATT1_C). The difference between the BATT monitor 54 and the BATT monitor 19 in FIG. 1 is that the BATT monitor 54 can detect that the BATT voltage becomes negative.

  The Vbis monitor 52 is a circuit that determines the voltage level of the output voltage (Vbis) of the booster circuit 50 based on the thresholds 6 and 7, and generates a determination signal (Vbis1_C). The difference between the Vbis monitor 52 and the Vbis monitor 10 of FIG. 1 is that the voltage levels of the thresholds 6 and 7 of the Vbis monitor 52 are different from the threshold levels 3 and 4 of the Vbis monitor 10.

  The boost controller 53 controls the start or stop of the boost operation of the boost circuit 50 by a determination signal (BATT1_C) from the BATT monitor 54, and controls the boost circuit 50 by the determination signal (Vbis1_C) from the Vbis monitor 52. This is a circuit that generates a control signal (CP1_C) for controlling the voltage level of the output voltage (Vbis).

  The capacitor 51 (Cbis1) is a capacitor for smoothing the output voltage Vbis of the booster circuit 50 when the voltage (BATT) of the battery 8 decreases to a minus voltage.

  In the present embodiment, the entirety of the load driving device 49 is integrally resin-sealed.

  The input circuit 48 has the following role.

  (1) When the voltage (BATT) of the battery 8 drops to a minus voltage, the boosting circuit 50 performs a boosting operation, generates at least a minimum voltage level (Vbis) at which the step-down power supply 4 can operate, and passes through the capacitor 51 (Cbis1). Drives the loads 2 and 3. Therefore, the voltage Vbis of the capacitor 51 (Cbis1) can be made lower than the voltage Vbis of the capacitor 40 (Cbis) of the first embodiment, and the conventional step-down power supply 4 can be used as it is. Further, since the capacitor 51 (Cbis1) is a capacitor for smoothing the output voltage Vbis of the booster circuit 50, the total capacitance value of the capacitor 51 (Cbis1) and the capacitor 39 (C2) is changed to the conventional input capacitor 6 (C1). Can be smaller.

  (2) When the voltage (BATT) of the battery 8 is a normal voltage, the boosting circuit 50 stops the boosting operation, and the voltage (BATT) of the battery 8 drives the loads 2 and 3 via the step-down power supply 4.

  In order to realize the above role, the operation mode of the input circuit 48 is set to one of the two modes shown in Table 3 below.

  FIG. 11 is a timing chart showing the operation of the load driving device 49 according to the second embodiment of the present invention.

  FIG. 12 is a flowchart illustrating the operation of the load driving device 49 according to the second embodiment of the present invention.

  The operation mode of the input circuit 48 will be described with reference to FIGS.

・ Normal mode → boost mode:
In the normal mode (S1201), when the voltage (BATT) of the battery 8 falls below the threshold value 5 (S1202: Yes), the operation enters the boost mode (S1203).

-Operation in the boost mode In the boost mode, since the capacitor 39 (C2) drives the loads 2 and 3, the input voltage (VB) of the step-down power supply 4 is reduced by discharging the capacitor 39 (C2). When the VB voltage falls below the Vbis voltage, the loads 2 and 3 are driven from the capacitor 51 (Cbis1) via the diode 47. As a result, when the voltage (Vbis) of the capacitor 51 (Cbis1) decreases, the boosting by the boosting circuit 50 starts. That is, when the Vbis monitor 52 and the BATT monitor 54 detect that the voltage (BATT) of the battery 8 has dropped below the threshold value 5 and the voltage (Vbis) has dropped below the threshold value 6, the boosting controller 53 causes the boosting circuit 50 to operate. Outputs a control signal (CP1_C) for starting the boosting operation, and the boosting circuit 50 starts boosting according to it. On the other hand, when the Vbis monitor 52 and the BATT monitor 54 detect that the voltage (BATT) of the battery 8 has dropped below the threshold value 5 and the voltage (Vbis) has risen above the threshold value 7, the boosting circuit 50 stops boosting.

・ Boost mode → Normal mode:
When the BATT monitor 54 detects that the voltage (BATT) of the battery 8 has risen above the threshold value 5 (S1204: No), the booster circuit 50 stops boosting and enters the normal mode (S1201). That is, when the VB voltage rises above the Vbis voltage, the battery 8 drives the loads 2 and 3 via the diode 5.

  The threshold values 5 to 7 are set as shown in Table 4 below. In the example of FIG. 11, thresholds 5 to 7 are set to 0 V, 7 V, and 7.5 V, respectively.

  As described above, when the input circuit 48 of the load driving device 49 according to the second embodiment is used, when the voltage (BATT) of the battery 8 decreases to a minus voltage, the boosting circuit 50 performs the boosting operation, and at least the step-down power supply 4 Generates the minimum voltage level (Vbis) that can operate, and drives the loads 2 and 3 via the capacitor 51 (Cbis1). Therefore, the voltage Vbis of the capacitor 51 (Cbis1) can be made lower than the voltage Vbis of the capacitor 40 (Cbis) of the first embodiment, and the conventional step-down power supply 4 can be used as it is. Further, since the capacitor 51 (Cbis1) is a capacitor for smoothing the output voltage Vbis of the booster circuit 50, the total capacitance value of the capacitor 51 (Cbis1) and the capacitor 39 (C2) is changed to the conventional input capacitor 6 (C1). Can be smaller.

  Next, a third embodiment of the present invention will be described. Except for the differences described below, the components of the load driving device of the third embodiment have the same functions as those of the first and second embodiments illustrated in FIGS. , And the description thereof will be omitted.

  Embodiments 1 and 2 are applicable only when the voltage (BATT) of the battery 8 drops to a minus voltage. When there are two types of states of the voltage (BATT) of the battery 8 lowering: a state in which the voltage drops to a negative voltage, and a state in which the voltage lowers than normal but does not lower to a negative voltage, the third embodiment is applied. is necessary.

  FIG. 13 is a block diagram illustrating a configuration of the load driving device 57 according to the third embodiment of the present invention. 13, FIG. 1 and FIG. 20 have the same reference numerals.

  The battery 8, the load 2, the load 3, and the step-down power supply 12 of the third embodiment are the same as those shown in FIG.

  The load driving device 57 includes an input circuit 56 and the step-down power supply 12.

  The input circuit 56 includes a booster circuit 14, a Vbis monitor 18, a boost controller 17, an auxiliary capacitor 40 (Cbis), a capacitor 39 (C2), a VB monitor 15, a BATT monitor 19, a capacitance connection unit 13, a capacitance connection controller 16, It comprises a Vbis monitor 2_59, a boost controller 2_58, and a boost circuit 2_55.

  The booster circuit 14, the Vbis monitor 18, the boost controller 17, the auxiliary capacitor 40 (Cbis), the capacitor 39 (C2), the VB monitor 15, the BATT monitor 19, the capacitance connection unit 13, and the capacitance connection controller 16 of the input circuit 56 1 is the same as that shown in FIG.

  The Vbis monitor 2_59 is a circuit that determines the voltage level of the output voltage (Vbis) of the booster circuit 14 based on the threshold 8, and generates a determination signal (Vbis_C2).

  The booster circuit 2_55 is a circuit that converts a low voltage to a high voltage. The difference between the booster circuit 14 and the booster circuit 2_55 is that the current drive capability of the booster circuit 2_55 is higher than that of the booster circuit 14 (that is, the current supply capability is higher). For example, the booster circuit 2 (55) is of an inductor type, and the booster circuit 14 is of a charge pump type. Accordingly, the booster circuit 2_55 can drive the loads 2 and 3 via the step-down power supply 12 while the voltage (BATT) of the battery 8 is falling within a positive value range.

  In the present embodiment, the entirety of the load driving device 57 is integrally resin-sealed.

  FIG. 14 is an explanatory diagram illustrating an example of the booster circuit 2_55 according to the third embodiment of the present invention.

  FIG. 14 shows an inductor type booster circuit as an example. The booster circuit 2_55 includes the inductor 66, the diode 5, and the MOS transistor 67 (SW3). The booster circuit 2_55 is a circuit that boosts a battery voltage (BATT) by a control signal (Boost_C) and outputs the boosted voltage as an output voltage (VB). The multiple of the boost can be adjusted by the ratio between the high and low periods of the control signal (Boost_C). The longer the high period of the control signal (Boost_C), the higher the multiple of the boost.

  The boost controller 2_58 stops the boosting operation of the booster circuit 2_55 and controls short-circuiting (through) the input and the output with the determination signal (BATT_C) from the BATT monitor 19, and controls the determination signal (from the Vbis monitor 2_59). Vbis_C2) to start the boosting operation of the boosting circuit 2_55.

  The input circuit 56 has the following role.

  (1) When the voltage (BATT) of the battery 8 drops to a minus voltage, the auxiliary capacitor 40 (Cbis) having a voltage (Vbis) higher than the normal voltage of the voltage (BATT) of the battery 8 drives the loads 2 and 3. Therefore, the total capacitance value of the auxiliary capacitor 40 (Cbis) and the capacitor 39 (C2) can be smaller than that of the conventional input capacitor 6 (C1).

  (2) When the voltage (BATT) of the battery 8 drops to a voltage lower than the normal voltage but higher than 0 V, the booster circuit 2 (55) boosts the voltage to the minimum voltage (VB) at which the step-down power supply 12 can operate. .

  (3) When the voltage (BATT) of the battery 8 is the normal voltage and the auxiliary capacitor 40 (Cbis) needs to be charged, the voltage (BATT) of the battery 8 is increased via the booster circuit 14 to the auxiliary capacitor 40 (Cbis). ), While driving the loads 2 and 3. When the voltage (BATT) of the battery 8 is the normal voltage and the auxiliary capacitor 40 (Cbis) does not need to be charged, the operation of the booster circuit 14 is stopped, and the voltage (BATT) of the battery 8 is changed to the loads 2 and 3. Drive.

  In order to realize the above role, the operation mode of the input circuit 56 is set to one of the four modes shown in Table 5 below. Two boosting modes are added to the three modes similar to the first embodiment.

  FIG. 15 is a timing chart showing the operation of the load driving device 57 according to the third embodiment of the present invention.

  FIG. 16 is a flowchart illustrating the operation of the load driving device 57 according to the third embodiment of the present invention.

  With reference to FIGS. 15 and 16, an operation of the input circuit 56 related to the two boosting modes will be described. Other modes are the same as in the first embodiment, and a description thereof will not be repeated. That is, the transition from the normal mode to the Cbis discharge mode and the transition from the Cbis charge mode to the normal mode are the same as in the first embodiment. When the voltage (BATT) of the battery 8 decreases to the minus voltage, the load driving device 57 operates in the same manner as the load driving device 11 of the first embodiment.

・ Cbis discharge mode → boost 2 mode:
In the Cbis discharge mode (S903), when the Vbis monitor 2_59 detects that the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) has dropped below the threshold value 8 (S1601: Yes), the input circuit 41 is set to the boost 2 mode. (S1602). That is, the capacitor connection unit 13 is connected, and the booster circuit 2_55 boosts the voltage. Battery 8 (BATT) drives loads 2 and 3 via booster circuit 2_55.

  When the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) is not lower than the threshold value 8 (S1601: No), the same processing as S904 to S907 of the first embodiment is executed. Therefore, a detailed description of these processes is omitted.

-Step-up 2 mode → Cbis charging mode:
When the Vbis monitor 18 and the BATT monitor 19 detect that the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) has dropped below the threshold 3 and the voltage of the battery 8 (BATT) has risen above the threshold 2 (S1603: Yes). , The input circuit 41 is set to the Cbis charging mode (S1604). That is, the capacity connection unit 13 is cut off, and the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) is boosted by the booster circuit 14 while the battery 8 (BATT) drives the loads 2 and 3. Thereafter, when the Vbis monitor 18 detects that the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) has risen above the threshold value 4 (S1605: Yes), the input circuit 41 is set to the normal mode (S901). This process is the same as S907 of the first embodiment.

  The threshold 8 is set as described in Table 6 below. Since the threshold values 1 to 4 are the same as those in the first embodiment, the description is omitted. In the example of FIG. 15, the threshold value 8 is set to 10.5V.

  As described above, by applying the third embodiment, it is possible to cope with two types of states, that is, a state in which the voltage (BATT) of the battery 8 has dropped to a minus voltage and a state in which the voltage (BATT) has dropped to a plus voltage lower than usual.

  Next, a fourth embodiment of the present invention will be described. Except for the differences described below, the components of the load driving device according to the fourth embodiment have the same functions as those of the first to third embodiments illustrated in FIGS. , And the description thereof will be omitted.

  In the case of the third embodiment, two boosting circuits, that is, the boosting circuit 14 and the boosting circuit 2_55 are required. Fourth Embodiment In order to reduce the circuit area, a fourth embodiment in which the booster circuit 14 and the booster circuit 2_55 are integrated into one booster circuit has been proposed.

  FIG. 17 is a block diagram illustrating a configuration of a load driving device 68 according to the fourth embodiment of the present invention. 17, 13, 1, and 20 have the same reference numerals.

  The battery 8, the load 2, the load 3, and the step-down power supply 12 of the fourth embodiment are the same as those in FIG.

  The load driving device 68 includes an input circuit 69 and the step-down power supply 12.

  The input circuit 69 includes a booster circuit 2_55, a Vbis monitor 18, a boost controller 72, an auxiliary capacitor 40 (Cbis), a capacitor 39 (C2), a VB monitor 15, a BATT monitor 19, a Vbis monitor 2_59, a MOS transistor 70 (SW1), And a MOS transistor 71 (SW2).

  The booster circuit 2_55 of the input circuit 69, the Vbis monitor 18, the auxiliary capacitor 40 (Cbis), the capacitor 39 (C2), the VB monitor 15, the BATT monitor 19, and the Vbis monitor 2_59 are the same as those in FIG. .

  The MOS transistor 70 (SW1) is a switch for selecting a connection destination of the input voltage (VB) of the step-down power supply 12.

  The MOS transistor 71 (SW2) is a switch for selecting a connection destination of the auxiliary capacitor 40 (Cbis).

  The boost controller 72 includes a determination signal (Vbis_C) from the Vbis monitor (18), a determination signal (Vbis_C2) from the Vbis monitor 2 (59), a determination signal (BATT_C) from the BATT monitor 19, and a signal from the VB monitor 15. This circuit controls the operation mode of the input circuit 69 in accordance with the determination signal (VB_C).

  In the present embodiment, the entirety of the load driving device 68 is integrally resin-sealed.

  The role of the input circuit 69 is the same as that of the input circuit 56 of the third embodiment. In order to realize these roles, the operation mode of the input circuit 69 is set to one of the four modes shown in Table 7 below.

  FIG. 18 is a timing chart illustrating the operation of the load driving device 68 according to the fourth embodiment of the present invention.

  FIG. 19 is a flowchart illustrating the operation of the load driving device 68 according to the fourth embodiment of the present invention.

  The operation of the input circuit 69 relating to each mode will be described with reference to FIGS.

・ Normal mode → Cbis discharge mode:
In the normal mode (S2001), when the voltage (BATT) of the battery 8 decreases, the capacitor 39 (C2) drives the loads 2 and 3, so that the input voltage (VB) of the step-down power supply 12 is discharged by discharging the capacitor 39 (C2). ) Decreases. When the VB monitor 15 detects that the input voltage (VB) has dropped below the threshold value 1 (S2002: Yes), the input circuit 69 is set to the Cbis discharge mode (S2003). That is, the MOS transistor 70 (SW1) and the MOS transistor 71 (SW2) are simultaneously turned on, the auxiliary capacitor 40 (Cbis) and the capacitor 39 (C2) are connected in parallel, and the energy stored in the auxiliary capacitor 40 (Cbis) is The loads 2 and 3 are driven by using these.

・ Cbis discharge mode → boost 3 mode:
When the Vbis monitor 2_59 detects that the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) has dropped below the threshold value 8 (S2004: Yes), the input circuit 69 is set to the boosting three mode (S2005). That is, the booster circuit 2_55 boosts the voltage of the battery 8 (BATT) so that VB and Vbis become the same voltage. The voltage (BATT) of the battery 8 drives the loads 2 and 3 via the booster circuit 2_55.

・ Boost 3 mode: → Boost 4 mode:
When the Vbis monitor 18 and the BATT monitor 19 detect that the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) has dropped below the threshold 3 and the voltage of the battery 8 (BATT) has risen above the threshold 2 (S2006: Yes). , The input circuit 69 is set to the boosting 4 mode (S2007). That is, the booster circuit 2_55 boosts the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) while the battery 8 (BATT) drives the loads 2 and 3.

・ Cbis discharge mode → boost 4 mode:
When the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) is not lower than the threshold value 8 (S2004: No), the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) is lower than the threshold value 3 and the battery When the Vbis monitor 18 and the BATT monitor 19 detect that the voltage (BATT) of No. 8 has risen above the threshold value 2 (S2009: Yes and S2010: Yes), the input circuit 69 is set to the boost 4 mode. That is, the booster circuit 2_55 boosts the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) while the battery 8 (BATT) drives the loads 2 and 3.

・ Cbis discharge mode → normal mode:
When the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) is not lower than the threshold 8 (S2004: No), the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) is higher than the threshold 3 and the battery 8 When the Vbis monitor 18 and the BATT monitor 19 detect that the voltage (BATT) has risen above the threshold 2 (S2009: Yes and S2010: No), the input circuit 69 is set to the normal mode (S2001). That is, the MOS transistor 71 (SW2) is always off, and the battery 8 (BATT) drives the loads 2 and 3.

・ Boost 4 mode → Normal mode:
In the step-up 4 mode (S2007 or S2011), when the Vbis monitor 18 detects that the voltage (Vbis) of the auxiliary capacitor 40 (Cbis) has risen above the threshold value 4 (S2008: Yes or S2012: Yes), the input circuit 69 The normal mode is set (S2001). That is, the boosting operation of the booster circuit 2_55 stops, the MOS transistor 70 (SW1) turns on, the MOS transistor 71 (SW2) turns off, and the battery 8 (BATT) drives the loads 2 and 3.

  When the input voltage (VB) is not lower than the threshold 1 (S2002: No), the same as when the input voltage (VB) is not lower than the threshold 1 in the first embodiment (S902: No). Since the processing (S908, S909) is executed, the description is omitted. However, in the case of S909: No, the input circuit 69 is set to the boost 4 mode.

  Further, since the threshold value of the fourth embodiment is the same as that of the third embodiment, the description is omitted.

  As described above, when the fourth embodiment is applied, two states, that is, a state in which the voltage (BATT) of the battery 8 is reduced to a minus voltage and a state in which the voltage (BATT) is reduced to a plus voltage lower than normal by one booster circuit Can respond to.

  Note that the present invention is not limited to the above-described embodiment, and includes various modifications. For example, the above-described embodiments have been described in detail for better understanding of the present invention, and are not necessarily limited to those having all the configurations described. Further, a part of the configuration of one embodiment can be replaced with the configuration of another embodiment, and the configuration of one embodiment can be added to the configuration of another embodiment. Also, for a part of the configuration of each embodiment, it is possible to add, delete, or replace another configuration.

1, 11, 49, 57, 68 Load driver 2, 3 Load 4, 12 Step-down power supply 5 Diode D
6 Capacitor C1
7 41, 48, 56, 69, input circuit 8 battery 9 inductive load 13 capacity connection unit 14, 50 booster circuit 15 VB monitor 16 capacity connection controller 17, 53, 72 booster controller 18, 52 Vbis monitor 19, 54 BATT Monitor 20, 27, 30, 34, 35, 43, 44 Input terminal 21, 29, 33, 38, 45 Output terminal 22 Hysteresis controller 23, 24 Resistance R1, R2
25 Reference voltage (Vref3)
26, 31 Comparator 28 Reference voltage (Vref1)
32 Reference voltage (Vref2)
36, 37 NAND AND 39 Capacitor C2
40 capacitor Cbis
42 AND 46 Logical NOT 47 Diode 51 Capacitor Cbis1
55 booster circuit 2
58 Boost controller 2
59 Vbis monitor 2
60-62 Diode 63-64 Capacitor 65 Phase inversion circuit 66 Inductor 67, 70, 71 MOS transistor

Claims (2)

A first capacitor connected to the first wiring, a second capacitor connected to the second wiring, and a power supply that charges the first capacitance, and boosts a voltage of the power supply. A first booster circuit for generating a voltage to be applied to the second wiring, and a connection for passing a current from the second wiring to the first wiring when the voltage of the first wiring decreases and parts, the possess,
The first wiring is connected to the power supply via the first booster circuit,
The connection unit switches a connection and a cutoff between the first booster circuit and the first wiring, and switches a connection and a cutoff between the first booster circuit and the second wiring. A second switch element;
The first booster circuit has a coil, a second diode, and a third switch element,
One end of the coil is connected to the power supply, the other end is connected to the anode of the second diode and the third switch element, and the cathode of the second diode is connected to the first switch element and the third switch element. 2, one end of the third switch element is connected to the anode of the second diode, and the other end is connected to ground,
When the voltage of the first wiring is higher than a first threshold, the first switch element is set to an on state, the second switch element and the third switch element are set to an off state,
When the voltage of the first wiring drops to the first threshold, the second switch element is turned on,
When the voltage of the second wiring drops to a fifth threshold value, the first switch element and the first switch element are configured to increase the voltage of the first wiring and the voltage of the second wiring to the same value. A second switching element and the third switching element perform a switching operation;
When the voltage of the power supply rises to a second threshold and the voltage of the second wiring is lower than a third threshold, the voltage of the second wiring is set to a value higher than the voltage of the first wiring. The first switch element, the second switch element, and the third switch element perform a switching operation so as to increase the voltage;
When the voltage of the second wiring rises to a fourth threshold higher than the third threshold, the first switch element is turned on, and the second switch element and the third switch element are turned off. A load driving device characterized by being set to: The load drive device according to claim 1, wherein
  The first wiring is connected to a step-down circuit that reduces the voltage of the first wiring to a predetermined value and applies the voltage to a load;
  The first threshold and the fifth threshold are equal to or higher than a minimum voltage at which the step-down circuit operates,
  The second threshold is equal to or higher than a minimum voltage at which the first booster circuit operates,
  The third threshold is higher than a voltage of the power supply,
  The third switch element repeats an ON state and an OFF state at a predetermined interval, and sets the first switch element and the second switch element to an OFF state when the third switch element is in an ON state. By setting the first switch element and the second switch element to the on state when the third switch element is in the off state, the voltage of the first wiring and the voltage of the second wiring are set. To the same value,
  The third switch element repeats an ON state and an OFF state at a predetermined interval, and sets the first switch element and the second switch element to an OFF state when the third switch element is in an ON state. When the third switch element is in the off state, the first switch element and the second switch element are alternately set to the on state, whereby the voltage of the second wiring is set to the first switch element. A load driving device for boosting a voltage to a value higher than a voltage of a wiring.

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