JP2010241184A - Airbag ignition circuit, and integrated circuit device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an airbag ignition circuit, and an integrated circuit device, which reduce power losses in a driver for igniting a squib. <P>SOLUTION: A voltage drop control unit 21 detects the value of a current running in a resistance element R1, turns on/off transistor Tr2 as an N-channel MOSFET to which the voltage boosted by a boosting converter 10 is applied based on the detected current value, and controls the output current to be the predetermined value. The voltage drop control unit 21 outputs the output voltage for a period in which an ignition IC 30 instructs the ignition signal as an EN signal to be input in the third input. A high side driver 31 and a low side driver 32 of the ignition IC 30 turn on transistors Tr3, Tr4 and ignite a squib 8 while the ignition signal is indicated. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an airbag ignition circuit and an integrated circuit device that ignite an ignition device for operating an airbag.

  FIG. 1 is a diagram showing a configuration of an airbag ignition circuit 9 according to a conventional technique. The airbag ignition circuit 9 boosts the voltage of the battery 7 by a boost converter 10 connected to the battery 7 via the diode D1, and accumulates electric charges in the capacitor C2 that is a backup capacitor with the boosted voltage. The airbag ignition circuit 9 ignites the squib 8 that is an ignition device by the electric charge accumulated in the capacitor C2, so that the airbag can be operated even if the power of the battery 7 is not supplied due to a vehicle collision or the like.

  Boost converter 10 includes a coil L1 connected in series to diode D1, a diode D2 connected in series to coil L1, a capacitor C2 as a backup capacitor connected to the output side of diode D2, and a connection between coil L1 and diode D2. The transistor Tr1 is controlled to be turned on and off so that the voltage of the transistor Tr1 composed of an N-channel MOSFET (Metal Oxide Semiconductor Field Effect Transistor) connected to the point and the capacitor C2 becomes a predetermined boosted voltage. The boost control unit 11 is included. A capacitor C1, which is a smoothing capacitor, is connected to a connection point between the diode D1 and the coil L1. By making the voltage due to the electric charge accumulated in the capacitor C2 by the boost converter 10 higher than the voltage of the battery 7, the capacitance of the capacitor C2 is reduced.

  The output of boost converter 10 is connected to a connection terminal 392 of an ignition integrated circuit (hereinafter referred to as “ignition IC”) 90 via a diode D4 for preventing backflow. The ignition IC 90 includes a high side driver 91 and a low side driver 32. The squib 8 is connected between the connection terminal 393 and the connection terminal 394 of the ignition IC 90, and the connection terminal 395 is grounded. The high side driver 91 includes a constant current control unit 911 and a transistor Tr3, and the low side driver 32 includes a driver 321 and a transistor Tr4. The transistor Tr3 is an N-channel MOSFET, the drain is connected to the connection terminal 392, the source is connected to the connection terminal 393, and the gate is connected to the constant current control unit 911. The transistor Tr4 is an N-channel MOSFET, and has a drain connected to the connection terminal 394, a source connected to the connection terminal 395, and a gate connected to the driver 321.

  When the ignition signal is instructed, the constant current control unit 911 turns on the transistor Tr3 (hereinafter referred to as “on”), and the driver 321 turns on the transistor Tr4 and ignites the squib 8. The constant current control unit 911 sets the current flowing through the transistor Tr3 to a predetermined current value so that no more current than necessary flows through the squib 8.

  The airbag ignition circuit described in Patent Document 1 is an airbag ignition circuit that performs constant current control and drives a high-side driver, similarly to the airbag ignition circuit 9 shown in FIG. This airbag ignition circuit charges the power supply voltage with a backup capacitor and performs constant current control, thereby making the current value of the current flowing through the squib constant.

  The ignition current limiting circuit for an airbag device described in Patent Document 2 has a configuration in which a squib is ignited by one driver instead of two drivers of a high side driver and a low side driver. This ignition current limiting circuit for an airbag device stores electric charge from a battery in a capacitor, and makes the current value of the current flowing through the squib constant by the ignition current limiting circuit.

  The airbag operating device described in Patent Document 3 is configured to charge a backup capacitor with a voltage boosted by a booster circuit without performing constant current control, and to ignite a squib with a single driver.

JP 2005-88748 A Japanese Patent Laid-Open No. 11-78771 JP 2006-44307 A

  FIG. 2 is a diagram for explaining voltage loss in the airbag ignition circuit 9. Boost converter 10 boosts voltage 12V (volt) of battery 7 to 25V, voltage drop V1 of diode D4 is 1V, resistance value of squib 8 is 2Ω (ohms), and resistance values of on-resistances of transistors Tr3 and Tr4 are 1Ω. Assuming that the current value flowing through the squib 8 by the constant current control unit 911 is 1.2 A (amperes), the voltage drop V3 at the squib 8 is 2Ω × 1.2A = 2.4 V, and the voltage drop at the low-side driver V4 is 1Ω × 1.2A = 1.2V, and the voltage drop V2 at the high side driver 91 is (output voltage of the boost converter) −V1−V3−V4 = 25V−1V−2.4V−1. 2V = 20.4V.

  The power loss in the low-side driver 32 is V4 × 1.2A = 1.2V × 1.2A = 1.44 W (Watt), but the power loss in the high-side driver 91 is V2 × 1.2A = 20. .4V × 1.2A = 24.48 W (Watt). In other words, if the time during which the ignition signal is instructed is 2 ms (milliseconds), 24.48 W of power loss occurs in the high-side driver 91 for 2 milliseconds. When the squib 8 is ignited with the voltage 12V of the battery 7, the voltage drop V2 at the high side driver 91 is 12V-4.6V = 7.4V, and the power loss is 7.4V × 1.2A = 8. .84W. Therefore, when the squib 8 is ignited with the voltage boosted by the boost converter, a power loss that is nearly three times as large as that generated when the squib 8 is ignited with the voltage of the battery 7 occurs in the high-side driver 91.

  Since the power loss in the high-side driver 91 is large, it is necessary to use a transistor having a size that does not break even with excessive power as the transistor Tr3, and since a large amount of power is required, the electrostatic capacity of the capacitor C2 that is a backup capacitor is required. The capacity must be increased.

  The airbag ignition circuit described in Patent Document 1 and the ignition current limiting circuit for an airbag device described in Patent Document 2 do not charge a backup capacitor with a voltage boosted using a boost converter. The voltage drop is smaller than when a boost converter is used, and power loss is also small. However, since the airbag ignition circuit 9 shown in FIG. 1 uses the boost converter 10 to increase the voltage of the backup capacitor, there is a problem that the voltage drop at the high-side driver 91 is large and the power loss is also large. is there. The airbag operating device described in Patent Document 3 also has the same problem because the voltage of the backup capacitor is increased using a booster circuit.

  An object of the present invention is to provide an airbag ignition circuit and an integrated circuit device that can reduce power loss in a driver that ignites a squib.

The present invention (1) includes a boosting unit that boosts a voltage from a DC power source;
A voltage output by the booster is applied, and a current output unit that outputs an output current to the load;
An airbag ignition circuit including an ignition unit that causes an output current output by the current output unit to flow through the squib when an ignition signal is instructed;
The current output unit is
A current detector for detecting the current value of the output current;
A control unit for controlling the current value of the output current to a predetermined current value based on the current value detected by the current detection unit,
The airbag ignition circuit according to claim 1, wherein the ignition unit includes a current limiting unit that limits a current flowing through the squib to less than a predetermined second current value.

Further, the present invention (7) includes a current output unit included in the airbag ignition circuit, a control unit, a voltage detection unit, a control unit among the ignition unit and the safing signal generation unit, a voltage detection unit and an ignition unit,
Based on the safing signal generated by the safing signal generator, an output permission signal for permitting the output of the output current and output voltage by the current output unit, and a permission signal for permitting the ignition unit to ignite are generated. An integrated circuit device comprising a safing control unit and integrated.

  According to the present invention (1), the voltage from the DC power source is boosted by the booster, the output current to the load is output by the current output unit to which the voltage boosted by the booster is applied, and the ignition unit When the ignition signal is instructed, the output current output by the current output unit is passed through the squib. The current output unit includes a current detection unit and a control unit, and the ignition unit includes a current limiting unit. The current detection unit detects the current value of the output current, and the control unit controls the current value of the output current to a predetermined current value based on the current value detected by the current detection unit. Then, the current flowing through the squib is limited to a value less than a predetermined second current value by the current limiting unit.

  Therefore, since the output current necessary for igniting the squib is supplied by the current output unit, the voltage boosted by the boosting unit is not applied to the ignition unit as it is, and the ignition unit, specifically, the squib is ignited. It is possible to reduce power loss in the driver. Furthermore, even when the squib ignition parts are connected in parallel, it is possible to prevent a current exceeding a predetermined second current value from flowing through each squib, and to prevent an increase in power loss. In addition, a minimum current required for ignition can be supplied to each squib.

  According to the invention (7), the control unit, the voltage detection unit, and the ignition unit among the current output unit, the control unit, the voltage detection unit, the ignition unit, and the safing signal generation unit included in the airbag ignition circuit. And, based on the safing signal generated by the safing signal generator, the safing control unit, an output permission signal for permitting the output of the output current and the output voltage by the current output unit, and ignition of the ignition unit A permission signal is generated to permit Therefore, since a part of the airbag ignition circuit is integrated, it is possible to reduce the size and reliability of the airbag ignition circuit.

It is a figure which shows the structure of the airbag ignition circuit 9 by a prior art. It is a figure for demonstrating the power loss of the airbag ignition circuit. It is a figure which shows the structure of the airbag ignition circuit 1 which is the 1st Embodiment of this invention. It is a figure for demonstrating the power loss of the airbag ignition circuit. It is a figure which shows the structure of the airbag ignition circuit 1a which is the 2nd Embodiment of this invention. It is a figure which shows the structure of the airbag ignition circuit 1b which is the 3rd Embodiment of this invention. It is a figure which shows the structure of the constant current step-down converter 20a. It is a figure which shows the structure of the constant current step-down converter 20b and ignition IC30c. It is a time chart which shows the relationship between a current fall signal and a current value switching signal. It is a time chart which shows the relationship between an ignition driver drive signal and a converter drive signal. It is a figure which shows the structure of the airbag ignition circuit 1c which is the 4th Embodiment of this invention. It is a figure which shows the structure of the airbag ignition circuit 1d which is the 5th Embodiment of this invention. It is a figure which shows the structure of the control unit 50 using ignition IC30e.

  FIG. 3 is a diagram showing a configuration of the airbag ignition circuit 1 according to the first embodiment of the present invention. The airbag ignition circuit 1 includes diodes D1 and D4, a capacitor C1, a step-up converter 10, a constant current step-down converter 20, and an ignition integrated circuit (hereinafter referred to as “ignition IC”) 30.

  The diode D1 has an anode connected to a DC power supply, for example, a battery 7 mounted on the vehicle, and a cathode connected to one end of the capacitor C1 and the input side of the boost converter 10. Capacitor C1 is a smoothing capacitor formed of, for example, an electric field capacitor, and one end is connected to the cathode of diode D1 and the input side of boost converter 10, and the other end is grounded.

  The step-up converter 10 that is a step-up unit includes a coil L1, a diode D2, a capacitor C2, a transistor Tr1, and a step-up control unit 11, and subtracts the voltage drop of the diode D1 from the voltage of the battery 7, for example, 12V (volt). The boosted voltage is boosted to 25V, for example. One end of the coil L1 is connected to the cathode of the diode D1 and one end of the capacitor C1, and the other end is connected to the anode of the diode D2 and the drain of the transistor Tr1. The diode D2 has an anode connected to the other end of the coil L1 and the drain of the transistor Tr1, and a cathode connected to one end of the capacitor C2 and the input side of the constant current step-down converter 20. Capacitor C2 is a backup capacitor formed of, for example, an electric field capacitor, and one end is connected to the cathode of diode D2 and the input side of constant current step-down converter 20, and the other end is grounded.

The transistor Tr1 is an N-channel MOSFET (Metal Oxide Semiconductor).
The drain is connected to the other end of the coil L1 and the anode of the diode D2, the source is grounded, and the gate is connected to the output of the boost control unit 11. The step-up control unit 11 switches the voltage of the charge accumulated in the capacitor C2 by switching the transistor Tr1 between a conductive state (hereinafter referred to as “on”) and a cutoff state (hereinafter referred to as “off”). The voltage is boosted to a voltage higher than the voltage applied to the coil L1.

  The constant current step-down converter 20 that is a current output unit includes a transistor Tr2, a diode D3, a coil L2, a resistance element R1, a capacitor C3, and a step-down control unit 21. The transistor Tr2 is an N-channel MOSFET, the drain as an input section is connected to the output side of the boost converter 10, specifically, the cathode of the diode D2 and one end of the capacitor C2, and the source as the output section is a diode. The cathode of D3 and one end of the coil L2 are connected, and the gate is connected to the output of the step-down control unit 21.

  The diode D3 has an anode grounded and a cathode connected to the source of the transistor Tr2 and one end of the coil 2. One end of the coil L2 is connected to the source of the transistor Tr2 and the cathode of the diode D3, and the other end is connected to one end of the resistance element R1 and the first input of the step-down control unit 21. The resistor element R1 has one end connected to the other end of the coil L2 and the first input of the step-down control unit 21, and the other end connected to one end of the capacitor C3, the anode of the diode D4, and the second input of the step-down control unit 21. It is connected to the. Capacitor C3 is a smoothing capacitor formed of, for example, an electric field capacitor, and one end is connected to the other end of resistance element R1, the anode of diode D4, and the second input of step-down control unit 21, and the other end is grounded. Yes.

  The step-down control unit 21 which is a current detection unit and a control unit includes three inputs, that is, first to third inputs, and the first input is connected to the other end of the coil L2 and one end of the resistance element R1. The second input is connected to the other end of the resistor element R1, the one end of the capacitor C3, and the anode of the diode D4, the third input is connected to the ignition IC 30, and the output is connected to the gate of the transistor Tr2. . The resistance element R1 is a resistance element for detecting the current value of the current flowing through the resistance element R1.

  The step-down control unit 21 has the same circuit configuration as that used in a conventional switching power supply, and detailed description thereof is omitted. The step-down control unit 21 detects the current value of the current flowing through the resistance element R1 based on the potential difference between both ends of the resistance element R1, and based on the detected current value, the current value determined in advance by the output current, for example, 1.2A The on / off state of the transistor Tr2 is controlled to be (ampere). Further, the step-down control unit 21 outputs an output current during a period in which an enable signal (hereinafter referred to as “EN signal”) to be described later input from the ignition IC 30 to the third input is instructed. The constant current step-down converter 20 outputs an output current from the connection point between the resistance element R1 and the capacitor C3, and outputs the voltage at the connection point between the resistance element R1 and the capacitor C3 as an output voltage.

  The diode D4 is a diode for preventing backflow. The anode is connected to the other end of the resistor element R1, the one end of the capacitor C3, and the second input of the step-down control unit 21, and the cathode is connected to the ignition IC 30. Yes.

  The ignition IC 30 is an integrated circuit that includes the high-side driver 31 and the low-side driver 32, and has connection terminals including connection terminals 391 to 395. The high side driver 31 includes a driver 311 and a transistor Tr3. The driver 311 has an ignition signal as an input and an output connected to the gate of the transistor Tr3. The transistor Tr3 is an N-channel MOSFET, the gate is connected to the output of the driver 311, the drain is connected to the connection terminal 392, and the source is connected to the connection terminal 393.

  The low side driver 32 includes a driver 321 and a transistor Tr4. The driver 321 receives an ignition signal as an input and has an output connected to the gate of the transistor Tr4. The transistor Tr4 is an N-channel MOSFET, the gate is connected to the output of the driver 321, the drain is connected to the connection terminal 394, and the source is connected to the connection terminal 395. The high side driver 31 and the low side driver 32 are ignition parts.

  The connection terminal 392 is connected to the cathode of the diode D4. That is, the output current of the constant current step-down converter 20 supplied from the diode D4 is supplied to the drain of the transistor Tr3 via the diode D4, and the voltage corresponding to the voltage drop of the diode D4 is calculated from the output voltage of the constant current step-down converter 20. The subtracted voltage is applied to the drain of the transistor Tr3. The connection terminal 393 is connected to one end of the squib 8 that is an ignition device, the connection terminal 394 is connected to the other end of the squib 8, and the connection terminal 395 is grounded. Therefore, when the transistor Tr3 and the transistor Tr4 are on, the output current of the constant current step-down converter 20 flows into the squib 8, and the squib 8 can be ignited.

  The ignition signal is a signal indicating that the vehicle has collided. When the ignition signal is instructed, specifically, when the ignition signal becomes high level, both the drivers 311 and 321 output high level, so that the transistors Tr3 and Tr4 are turned on. If the ignition signal is not instructed, specifically, when the ignition signal becomes low level, both the drivers 311 and 321 output a low level, so that the transistors Tr3 and Tr4 are turned off. The ignition signal is also input as the EN signal to the third input of the step-down control unit 21 connected to the connection terminal 391. The step-down control unit 21 outputs an output current when the EN signal is instructed, and does not output an output current when the EN signal is not instructed.

  FIG. 4 is a diagram for explaining the power loss of the airbag ignition circuit 1. The voltage boosted by the boost converter 10 is 25V, the voltage drop V1 of the diode D4 is 1V, the resistance value of the squib 8 is 2Ω (ohms), the resistance value of the on-resistance of the transistors Tr3 and Tr4 is 1Ω, and the constant current step-down converter 20 When the current value of the output current is 1.2 A, the voltage drop V2 at the high side driver 91 is 1Ω × 1.2A = 1.2V, and the voltage drop V3 at the squib 8 is 2Ω × 1.2A = The voltage drop V4 at the low-side driver is 1Ω × 1.2A = 1.2V.

  Both the power loss in the low-side driver 32 and the high-side driver 91 is 1.2 V × 1.2 A = 1.44 W (watts). The airbag ignition circuit 9 shown in FIG. 1 has a power loss of 24.48 W at the high-side driver 91 as described in FIG. 2, but the airbag ignition circuit 1 shown in FIG. It becomes 44W, and a power loss can be reduced significantly.

  In addition, since the power to be supplied can be reduced, the capacitance of the capacitor C2, which is a backup capacitor, can also be reduced. For example, assuming that the power efficiency of the constant current step-down converter 20 is 80% and the input voltage to the constant current step-down converter 20 is operable at 8 V or more, the minimum required capacitance of the capacitor C2 is shown in FIG. In the airbag ignition circuit 9, it is 141 μF (farad), but in the airbag ignition circuit 1 shown in FIG. 3, it may be 52 μF. Therefore, the size of the capacitor C2 can be reduced, and the airbag ignition circuit 1 can be reduced in size.

  FIG. 5 is a diagram showing a configuration of an airbag ignition circuit 1a according to the second embodiment of the present invention. The airbag ignition circuit 1a includes diodes D1 and D4, a capacitor C1, a boost converter 10, a constant current step-down converter 20, and an ignition IC 30a. Among the components of the airbag ignition circuit 1a, the same components as those of the airbag ignition circuit 1 shown in FIG. 3 are denoted by the same reference numerals and description thereof is omitted to avoid duplication.

  In order to ignite the four squibs 8, the airbag ignition circuit 1a uses an ignition IC 30a having four ignition circuits 34 instead of the ignition IC 30 shown in FIG. The ignition IC 30a includes an ignition control unit 33 and four ignition circuits 34. Hereinafter, each of the four ignition circuits is referred to as an ignition circuit 34a to 34d, and each of the four squibs 8 is referred to as a squib 8a to 8d. The ignition IC 30a shown in FIG. 5 shows four ignition circuits 34a to 34d, but is not limited to four, and the same number of ignition circuits as the number of squibs are provided. When the ignition signal is instructed, the ignition control unit 33 outputs an ignition driver drive signal for instructing the ignition circuit 34 to ignite simultaneously in the same time zone, and the EN signal is connected to the connection terminal 391. 21 to the third input. The time zone for ignition is, for example, 2 milliseconds.

  The ignition circuit 34a includes a high side driver 31a and a low side driver 32. The high side driver 31a uses a current limiting unit 312 instead of the driver 311 of the high side driver 31 shown in FIG. A squib 8a is connected between the connection terminal 393 and the connection terminal 394 of the ignition circuit 34a. The current limiting unit 312 has the same circuit configuration as that of the conventional constant current control unit 911 shown in FIG. The current limiting unit 312 controls the gate voltage of the transistor Tr3 so that the current value of the current flowing through the transistor Tr3 is less than a predetermined second current value. The predetermined second current value is, for example, 1.3A.

  The ignition circuits 34b to 34d have the same circuit configuration as the ignition circuit 34a, and a description thereof will be omitted to avoid duplication. A cathode of the diode D4 is connected to each connection terminal 392 of the ignition circuits 34b to 34d, and squibs 8b to 8d are connected to the ignition circuits 34b to 34d, respectively. The ignition circuit 34 is an ignition unit.

  Each ignition circuit 34 and each squib 8 has impedance variations, and unless the current limiting unit 312 is used, the current concentrates on the ignition circuit 34 having the smallest impedance of the ignition circuit 34 and the squib 8. The current required for other ignition circuits cannot be passed. By using the current limiter 312, the current value of the current flowing through each ignition circuit 34 can be limited to less than a predetermined second current value, and the squib is not concentrated on any ignition circuit 34. A current equal to or higher than a predetermined third current value necessary for igniting 8 can be supplied. The predetermined third current value is, for example, 1.2A.

  When the number of squibs 8 is four, the current value of the output current output from the constant current step-down converter 20 is a current value obtained by adding a predetermined third current value to a current value obtained by multiplying a predetermined second current value by three. To do. Therefore, a predetermined third current value, for example, a current of 1.2 A or more can be passed through all the ignition circuits 34.

  Since all of the ignition circuits 34 can be supplied with a current equal to or greater than a predetermined third current value, all the squibs 8 can be ignited, and no squibs 8 that do not ignite remain, so the constant current step-down converter 20 The output voltage does not increase. Therefore, the power loss of any ignition circuit 34 can be kept small. For example, even if the current value of the current flowing through the ignition circuit 34 is 1.3 A, the power loss in the transistors Tr3 and Tr4 is 1.3 A × 1.3 A × 1Ω = 1.69 W. The loss is much smaller than 24.48W.

  In the airbag ignition circuit 1 a shown in FIG. 5, the current limiting unit 312 is used for the high side driver 31 a, but may be used for the low side driver 32. Even when used for the low-side driver 32, the same effects as those obtained when used for the high-side driver 31a can be obtained.

  FIG. 6 is a diagram showing a configuration of an airbag ignition circuit 1b according to the third embodiment of the present invention. The airbag ignition circuit 1b includes diodes D1 and D4, a capacitor C1, a boost converter 10, a constant current step-down converter 20a, and an ignition IC 30b. Among the components of the airbag ignition circuit 1a, the same components as those of the airbag ignition circuit 1a shown in FIG. 5 are denoted by the same reference numerals and description thereof is omitted to avoid duplication.

  The airbag ignition circuit 1b uses an ignition IC 30b instead of the ignition IC 30a shown in FIG. 5 in order to change the output current of the constant current step-down converter 20a according to the number of squibs 8 that are simultaneously ignited in the same time period. The constant current step-down converter 20a is used instead of the constant current step-down converter 20 shown in FIG. 5, and a current switching signal is sent from the ignition IC 30b to the constant current step-down converter 20a.

  The ignition IC 30b uses an ignition control unit 33a instead of the ignition control unit 33 shown in FIG. The ignition control unit 33a, which is an ignition number generation unit, outputs a converter drive signal, an ignition driver drive signal, and a current switching signal based on the input ignition signal. The converter drive signal is output as an EN signal to the third input of the constant current step-down converter 20a connected to the connection terminal 391. The ignition driver drive signal is sent to the ignition circuits 34a to 34d as individual signals. The converter drive signal is the same signal as the EN signal output from the ignition control unit 33, and the ignition driver drive signal is the same signal as the ignition driver drive signal output from the ignition control unit 33. The current switching signal is a signal representing the number of squibs that are ignited simultaneously in the same time zone, and is sent from the ignition control unit 33a to the constant current step-down converter 20a connected to the connection terminal 396.

  The ignition signal shown in FIG. 3 and FIG. 5 is a signal that is output for a period of instructing ignition, but the ignition signal input to the ignition control unit 33a is instructed as a pulse-like signal at the start and end of ignition. The squib identification information for igniting simultaneously in the same time zone is indicated as a serial signal. The squib identification information is information for identifying each squib 8.

  The ignition control unit 33a acquires from the ignition signal an ignition start instruction, an ignition end instruction, and squib identification information for simultaneously igniting in the same time zone. The ignition control unit 33a outputs a converter drive signal based on the ignition start instruction and the ignition end instruction, and generates an ignition driver based on the ignition start instruction, the ignition end instruction, and squib identification information for simultaneously igniting in the same time zone. Based on the squib identification information for igniting simultaneously in the same time zone, a drive signal is output, the number of squibs to be ignited simultaneously in the same time zone is calculated, and the calculated number of squibs is output as a current switching signal.

  The constant current step-down converter 20a uses a step-down control unit 21a instead of the step-down control unit 21 shown in FIG. The step-down control unit 21 a has a fourth input in addition to the first to third inputs, and the fourth input is connected to the connection terminal 396. A current switching signal from the ignition control unit 33a is input to the fourth input via the connection terminal 396. In FIG. 6, two signal lines are shown as signal lines for the current switching signal. However, three or more signal lines may be used, and the current switching signal may be sent as a serial signal using one signal line.

  The step-down control unit 21a outputs an output current corresponding to the number of squibs indicated by the current value switching signal input to the fourth input. Specifically, when the number of squibs indicated by the current value switching signal is n, the predetermined second current value is 1.3 A, and the predetermined third current value is 1.2 A, the output current is 1. 3A × (n−1) + 1.2A.

  FIG. 7 is a diagram showing a configuration of the constant current step-down converter 20a. The step-down control unit 21a included in the constant current step-down converter 20a includes a constant current control unit 211, a voltage detection comparator 212, and a constant voltage source 213.

  In the constant current control unit 211, the first to fourth inputs to the constant current step-down converter 20 are input as they are, and the output of the voltage detection comparator 212 is also input. The output of the constant current control unit 211 is connected to the gate of the transistor Tr2 as the output of the constant current step-down converter 20a. The voltage detection comparator 212, which is a voltage detection unit, compares the voltage at the connection point between the resistor element R1 and the capacitor C3 with the voltage of the constant voltage source 213, and outputs an output when the output voltage is equal to or higher than the voltage of the constant voltage source 213. A high voltage detection signal indicating that the voltage has become equal to or higher than the voltage of the constant voltage source 213 is sent to the constant current control unit 211.

  The constant current control unit 211 has the same circuit configuration as that used in a conventional switching power supply, and detailed description thereof is omitted. The constant current control unit 211 calculates the current value of the current flowing through the resistance element R1 from the potential difference between both ends of the resistance element R1, and based on the calculated current value, the transistor Tr2 The output current is output during the period when the EN signal is instructed. When the high voltage detection signal is received from the voltage detection comparator 212, on / off of the transistor Tr2 is controlled so that the output voltage does not exceed the voltage of the constant voltage source 213. Since the constant current step-down converter 20a controls the output voltage to be a predetermined voltage, for example, 5.8V, the voltage of the constant voltage source 213 can be set to a value slightly higher than 5.8V, for example, 6V. For example, even if the output voltage rises to 5.8 V or higher, it can be suppressed to 6 V at the maximum, so that the power loss can be reduced.

  The squib 8 is in an open state after ignition, and the current flowing before ignition does not flow. Since the current value of the total current flowing through the squib 8 that is not ignited is smaller than the current value of the current that the constant current step-down converter 20a is about to output, the output voltage increases, but the constant current control unit 211 outputs Since the voltage is controlled so as not to exceed the voltage of the constant voltage source 213, the output voltage of the constant current step-down converter 20a does not rise to the output voltage of the boost converter 10, and an increase in voltage loss in the ignition circuit 34 is suppressed. be able to.

  FIG. 8 is a diagram showing the configuration of the constant current step-down converter 20b and the ignition IC 30c. Constant current step-down converter 20b and ignition IC 30c are used instead of constant current step-down converter 20a and ignition IC 30b shown in FIG. The components of the constant current step-down converter 20b are the same as those of the constant current step-down converter 20a, but the output of the voltage detection comparator 212 is also connected to the ignition IC 30.

  The ignition IC 30c adds a timer unit 35 to the ignition IC 30b shown in FIG. 6, and uses an ignition control unit 33c instead of the ignition control unit 33a. The ignition control unit 33c outputs the same signal as the EN signal and the ignition driver drive signal output from the ignition control unit 33a. Further, the ignition control unit 33c outputs a current value switching signal indicating the number of squibs that are simultaneously ignited in the same time zone, but outputs a current value switching signal each time a current lowering signal is instructed from the timer unit 35. Reduce the number of squibs by one.

  The timer unit 35, which is a current value switching signal generation unit, outputs a high voltage detection signal from the voltage detection comparator 212 and continues to output a predetermined time after the high voltage detection signal is output while the output of the high voltage detection signal continues. Each time it passes, it outputs a pulsed current drop signal.

  FIG. 9 is a time chart showing the relationship between the current drop signal and the current value switching signal. The ignition signal indicates a serial signal. When an ignition start is instructed at time t1, the ignition control unit 33c instructs, for example, the number of squibs “4” by the current value switching signal. When at least one of the squibs 8 ignites, no current flows through the ignited squib 8. The constant current step-down converter 20b tries to output an output current having a predetermined current value. However, since the current that actually flows decreases, the output voltage increases.

  When the output voltage increases and becomes equal to or higher than the voltage of the constant voltage source 213, the voltage detection comparator 212 outputs a high voltage detection signal. When the voltage detection comparator 212 outputs a high voltage detection signal at time t2, the timer unit 35 outputs a high voltage detection signal every time a predetermined time T1 elapses after the high voltage detection signal is output. And output a pulse-like current drop signal.

  For example, the timer unit 35 outputs a pulsed current decrease signal at time t3 when time T1 has elapsed from time t2. The ignition control unit 33c outputs a current value switching signal obtained by subtracting the number of squibs from “4” to “3” by the current decrease signal at time t3. When the constant current step-down converter 20b receives the current value switching signal with the squib number “3” from the ignition control unit 33c, the constant current step-down converter 20b reduces the output current with the squib number “4” to the output current with the squib number “3”. Even if the constant current step-down converter 20b reduces the output current of the squib number “4” from the output current of the squib number “3”, if the voltage detection comparator 212 continues to output the high voltage detection signal, the timer unit 35 A pulse-shaped current drop signal is output at time t4 when time T1 has elapsed from time t3.

  The ignition control unit 33c outputs a current value switching signal obtained by subtracting the number of squibs from “3” to “2” by the current decrease signal at time t4. The constant current step-down converter 20b reduces the output current of the squib number “3” from the output current of the squib number “3” to the output current of the squib number “2” by the current value switching signal indicating the squib number “2” at the time t4. When the voltage is lower than the voltage of the voltage source 213, the high voltage signal is not output, and the current drop signal is not output thereafter.

  As described above, the constant current step-down converter 20b and the ignition IC 30c ignite the squib 8 to reduce the output current step by step when the output voltage rises, thereby suppressing the rise in the output voltage. Can be reduced, and energy stored in the capacitor C2 as a backup capacitor can be saved.

  When the high voltage detection signal is output, the constant current step-down converter 20b and the ignition IC 30c shown in FIG. 8 perform subtraction of the number of squibs by the ignition control unit 33c of the ignition IC 30c to instruct the constant current step-down converter 20b. However, the timer unit 35 may be provided in the step-down control unit 21b, and the constant current control unit 211 may subtract the number of squibs in response to the output of the timer unit 35.

  FIG. 10 is a time chart showing the relationship between the ignition driver drive signal and the converter drive signal. The ignition signal outputs a pulse for instructing the start of ignition at time t5 and a pulse for instructing the end of ignition at time t7. The ignition control unit 33a or the ignition control unit 33c outputs an ignition driver drive signal during a period from the ignition start instruction at time t5 to time t8, and a converter drive signal during the period from time t6 to time t7 of the ignition end instruction. Output EN signal. The time t6 is the time when the predetermined first delay time T2 has elapsed from the time t5, and the time t8 is the time when the predetermined second delay time T3 has elapsed from the time t7.

  When the converter drive signal is output at time t6, the constant current step-down converter 20a and the constant current step-down converter 20b output the output current (indicated as “converter output current” in the figure) and the output voltage (in the figure as “converter output voltage”). Output).

  Thus, when starting ignition, after starting the output of the ignition driver drive signal and starting the drive of the high side driver 31a and the low side driver, that is, after turning on the transistors Tr3 and Tr4, the converter drive signal The output of the output current and the output voltage is started. When the ignition is terminated, the output of the converter drive signal is stopped, the output of the output current and the output voltage is stopped, the output of the ignition driver drive signal is stopped, and the high side driver 31a and the low side driver are stopped. Driving is stopped, that is, the transistors Tr3 and Tr4 are turned off. Therefore, since the transistors Tr3 and Tr4 are not turned on, no current flows and the output voltage can be prevented from rising. For example, when the voltage detection comparator 212 is not provided, if the output current is output before the driver is driven, not the order of the timing chart shown in FIG. 10, the output voltage rises to the voltage boosted by the boost converter 10. However, the voltage loss increases.

  FIG. 11 is a diagram showing a configuration of an airbag ignition circuit 1c according to the fourth embodiment of the present invention. The airbag ignition circuit 1c includes diodes D1 and D4, a capacitor C1, a step-up converter 10, a constant current step-down converter 20a, an ignition IC 30d, a safing determination unit 40, and a collision determination unit 41. Among the constituent elements of the airbag ignition circuit 1c, the same constituent elements as those of the airbag ignition circuit 1b shown in FIG.

  The airbag ignition circuit 1c is provided with a safing determination unit 40 that generates a safing signal and a collision determination unit 41 that generates an ignition signal in the airbag ignition circuit 1b shown in FIG. IC30d is used.

  The safing determination unit 40 which is a safing signal generation unit includes an acceleration sensor 401 and a microcomputer (hereinafter referred to as “microcomputer”) 402. The acceleration sensor 401 is a detector that detects acceleration generated in the vehicle due to the collision of the vehicle. When the microcomputer 402 determines that the acceleration detected by the acceleration sensor 401 is acceleration caused by the collision, the safing signal and Output EN signal. The EN signal is input to the third input of the step-down control unit 21a, and the safing signal is input to the connection terminal 397 of the ignition IC 30d.

  The collision determination unit 41 that is an ignition signal generation unit includes an acceleration sensor 411 and a microcomputer 412. The acceleration sensor 411 is a detector that detects acceleration generated in the vehicle due to a vehicle collision, and the microcomputer 412 outputs an ignition signal when it is determined that the acceleration detected by the acceleration sensor 411 is acceleration caused by the collision. To do. The ignition signal is input to the connection terminal 398 of the ignition IC 30d.

  The ignition IC 30d uses an ignition control unit 33d instead of the ignition control unit 33a shown in FIG. 6, and includes a connection terminal 397 for connecting a safing signal and a connection terminal 398 for connecting an ignition signal. Yes. The ignition control unit 33d outputs an ignition driver drive signal when both the safing signal and the ignition signal instruct the ignition start, and when neither the safing signal nor the ignition signal instruct the ignition start or the safing signal Alternatively, when the ignition signal instructs the end of ignition, the ignition driver drive signal is not output. The number of squibs that ignite simultaneously in the same time zone is calculated based on the squib identification information that ignites simultaneously in the same time zone indicated by the ignition signal from the collision determination unit 41, and the ignition control unit 33d indicates the calculated number of squibs. The current value switching signal is input to the fourth input of the step-down control unit 21a.

  Since the ignition control unit 33d outputs an ignition driver drive signal and ignites the squib 8 only when both the safing signal and the ignition signal instruct the ignition start, the ignition control unit 33d includes the safing determination unit 40 and the collision determination unit 41. Even if one of the above malfunctions and the safing signal or the ignition signal is erroneously output, the squib 8 is not ignited.

  FIG. 12 is a diagram showing a configuration of an airbag ignition circuit 1d according to the fifth embodiment of the present invention. The airbag ignition circuit 1d includes diodes D1, D3, D4, capacitors C1, C3, a boost converter 10, a transistor Tr2, a coil L2, a resistance element r1, and an ignition IC 30e. Among the components of the airbag ignition circuit 1d, the same components as those of the airbag ignition circuit 1c shown in FIG. 11 are designated by the same reference numerals and description thereof is omitted to avoid duplication.

  The ignition IC 30e is configured to include a step-down control unit 21a that constitutes the constant current step-down converter 20a, a safing control unit 36 is added, and an ignition control unit 33e is used instead of the ignition control unit 33d shown in FIG. For connecting the connection terminal 399 for connecting the output of the constant current control unit 211, the connection terminal 390 for connecting the first input of the constant current control unit 211, and the second input of the constant current control unit 211 The connection terminal 389 is formed.

  When the ignition control is instructed by the safing signal, the safing control unit 36 starts outputting the EN signal to the third input of the constant current control unit 211 and outputs the permission signal to the ignition control unit 33e. To start. When the end of ignition is instructed by the safing signal, the output of the EN signal to the third input of the constant current control unit 211 is stopped and the output of the permission signal to the ignition control unit 33e is stopped.

  When the ignition start is instructed by the ignition signal and the permission signal is output, the ignition control unit 33e starts outputting the ignition driver drive signal, and the ignition signal is instructed to end the ignition or the permission signal is When it is not output, the output of the ignition driver drive signal is stopped. The ignition control unit 33e calculates the number of squibs to be ignited simultaneously in the same time zone based on the squib identification information to be ignited simultaneously in the same time zone indicated by the ignition signal, and generates a current value switching signal representing the calculated squib number. And output to a fourth input of the constant current control unit 211.

  In the airbag ignition circuit 1d shown in FIG. 12, a part of the constant current step-down converter 20a, specifically, the step-down control unit 21a is incorporated in the ignition IC 30e, but a part of the step-up converter 10 such as the step-up control unit 11 is provided. It is also possible to take in the ignition IC 30e.

  Since the airbag ignition circuit 1d is integrated by including a part of the constant current step-down converter 20a, specifically, the step-down control unit 21a in the ignition IC, the airbag ignition circuit 1d is reduced in size and reliability. Is possible.

  FIG. 13 is a diagram showing a configuration of the control unit 50 using the ignition IC 30e. The control unit 50 as a control device includes diodes D1, D3, D4, capacitors C1, C3, boost converter 10, transistor Tr2, coil L2, resistance element r1, ignition IC 30e, safing determination unit 40a, and collision determination unit 41. A power supply terminal 51 and a connection terminal group 52 are formed.

  Among the components of the control unit 50, the same components as the components of the airbag ignition circuit 1c shown in FIG. 11 and the same components as the components of the airbag ignition circuit 1d shown in FIG. For this reason, the same reference numerals are used and description thereof is omitted. The diodes D1, D3, D4, capacitors C1, C3, boost converter 10, transistor Tr2, coil L2, resistance element r1, and ignition IC 30e included in the control unit 50 constitute an airbag ignition circuit 1d.

  The battery 7 is connected to the power supply terminal 51, and the power supply terminal 51 is connected to the anode of the diode D1. The connection terminal group 52 is a connection terminal connected to connection terminals 393 and 394 formed in each ignition circuit 34, and squibs 8 a to 8 d are connected to connection terminals corresponding to the connection terminals 393 and 394 of each ignition circuit 34. Are connected to each other. The safing determination unit 40a outputs a safing signal similarly to the safing determination unit 40 shown in FIG. 11, but does not output an EN signal. The EN signal is output from the safing control unit 36. Since the control unit 50 includes the integrated ignition IC 30e, the control unit 50 can be reduced in size and increased in reliability.

  As described above, the voltage from the DC power source is boosted by the boost converter 10, and the output current to the load is output by the constant current step-down converter 20 to which the voltage boosted by the boost converter 10 is applied, and the high side driver 31. When the ignition signal is instructed by the low-side driver 32, the output current output by the constant current step-down converter 20 is passed through the squib 8. Furthermore, the constant current step-down converter 20 includes a step-down control unit 21. The step-down control unit 21 detects the current value of the output current, and the current value of the output current is controlled to a predetermined current value based on the detected current value.

  Therefore, since the output current necessary for igniting the squib 8 is supplied by the constant current step-down converter 20, the voltage boosted by the step-up converter 10 is not applied to the high-side driver 31 as it is, and the high-side driver 31 The power loss at can be reduced.

  Further, the ignition circuit 34 includes a current limiting unit 312 that limits the current flowing through the squib 8 to be less than a predetermined second current value, and the current flowing through the squib 8 is predetermined by the current limiting unit 312. Limited to less than. Therefore, even when the ignition circuit 34 of the squib 8 is connected in parallel, it is possible to prevent the current exceeding the predetermined second current value from flowing through each squib 8 and to prevent an increase in power loss. In addition, a minimum current required for ignition can be supplied to each squib 8.

  Furthermore, the number of squibs that are ignited simultaneously in the same time zone is generated by the ignition control unit 33a, and the constant current step-down converter 20 sets 1 to a predetermined second current value from the number generated by the ignition control unit 33a. A value obtained by adding the current value obtained by multiplying the subtracted number and the predetermined third current value which is a current value less than the predetermined second current value is set as the predetermined current value. Therefore, even if the number of squibs 8 to be ignited changes according to the collision type of the vehicle, for example, when the vehicle collides from the side, the side airbag and the curtain airbag are operated, and the front airbag and the seat are operated. Even if the belt pretensioner is not operated, the output current is changed according to the number of the squibs 8, so that the current exceeding the minimum current value necessary for ignition can be supplied to each squib 8.

  Further, constant current step-down converter 20 includes a voltage detection comparator 212. The voltage detection comparator 212 detects the output voltage, and the step-down control unit 21 controls the output voltage to be less than a predetermined voltage based on the output voltage detected by the voltage detection comparator 212. Accordingly, after the squib 8 is ignited, no current flows through the squib 8 that has been ignited, and even if the output voltage rises, the output voltage is controlled to be less than a predetermined voltage. Can be prevented from increasing.

  Further, when the timer unit 35 detects that the output voltage has become equal to or higher than a predetermined voltage by the voltage detection comparator 212, a current value switching signal for switching the current value is generated every time a predetermined time elapses. Whenever the current value switching signal is generated by the timer unit 35 by the ignition control unit 33c, 1 is subtracted from the number generated by the ignition control unit 33c. Therefore, it is possible to prevent an excessive amount of current from flowing through the squib 8 that has not been ignited, reduce an increase in power loss, and save energy stored in the capacitor C2, which is a backup capacitor.

  Further, the constant current step-down converter 20 outputs the output current and the output voltage from the time when the predetermined first delay time has elapsed from the time when the ignition signal is instructed to the time when the ignition signal is no longer instructed, and the ignition circuit 34, the output current output by the constant current step-down converter 20 can be output to the squib from the time when the ignition signal is instructed to the time when the predetermined second delay time elapses from the time when the ignition signal is no longer instructed. It is said. Therefore, the constant current step-down converter 20b supplies current to the squib while the driver is driven, both at the start of ignition and at the end of ignition, so that no current flows through the squib. The rise in output voltage due to can be suppressed. For example, when the voltage detection comparator 212 is not provided, when the ignition is started, if the output of the constant current step-down converter 20b is started before the driver is driven, no current flows through the squib, and the output voltage is increased. As a result, the voltage rises to the boosted voltage.

  Further, the collision determination unit 41 detects the acceleration of the vehicle, and based on the detected acceleration, it is determined whether the vehicle has collided. When it is determined that the vehicle has collided, an ignition signal is generated, The safing determination unit 40 detects the acceleration of the vehicle. Based on the detected acceleration, it is determined whether the vehicle has collided. When it is determined that the vehicle has collided, a safing signal is generated. . Then, when an ignition signal is generated by the collision determination unit 41 and a safing signal is generated by the safing determination unit 40 by the ignition circuit 34, the output current output by the constant current step-down converter 20 is passed through the squib. When the safing determination unit 40 generates a safing signal by the constant current step-down converter 20, an output current and an output voltage are output. Accordingly, since the collision determination unit 41 and the safing determination unit 40 perform the collision determination twice, even if one of the circuits breaks down and erroneously determines the collision, the airbag is prevented from operating erroneously. be able to.

  Further, the constant current step-down converter 20, the step-down control unit 21, the voltage detection comparator 212, the step-down control unit 21 among the ignition circuit 34 and the safing determination unit 40, the voltage detection comparator 212, and the ignition included in the airbag ignition circuit 1 c The circuit 34 and the safing control unit 36 are integrated and output based on the safing signal generated by the safing determination unit 40 by the safing control unit 36. An enable signal for permitting the output of the voltage and an enable signal for allowing the ignition circuit 34 to ignite are generated. Therefore, since a part of the airbag ignition circuit 1c is integrated, the airbag ignition circuit 1d can be downsized and highly reliable.

  Further, it includes a boost converter 10, a transistor Tr2, a collision determination unit 41, a safing determination unit 40, and an ignition IC 30e included in the airbag ignition circuit 1d. Therefore, since the airbag ignition circuit 1d configured to include the ignition IC 30e is used, the control unit 50 can be downsized and highly reliable.

DESCRIPTION OF SYMBOLS 1,1a-1d, 9 Airbag ignition circuit 7 Battery 8,8a-8d Squib 10 Boost converter 11 Boost control part 20,20a, 20b Constant current step-down converter 21,21a, 21b Step-down control part 30,30a-30e, 90 Ignition IC
31, 31a, 91 High-side driver 32 Low-side driver 33, 33a, 33c-33e Ignition control unit 34a-34d Ignition circuit unit 35 Timer unit 36 Safe control unit 40, 40a Safe determination unit 41 Collision determination unit 50 Control unit 51 Power supply terminal 52 Connection terminal group 91, 211 Constant current control unit 212 Voltage detection comparator 213 Constant voltage source 311, 321 Driver 312 Current limiting unit 389-399 Connection terminal 401, 411 Acceleration sensor 402, 412 Microcomputer C1-C3 Capacitor D1-D4 Diode L1, L2 Coil R1 Resistance element Tr1-Tr4

Claims (7)

A booster that boosts the voltage from the DC power supply;
A voltage output by the booster is applied, and a current output unit that outputs an output current to the load;
An airbag ignition circuit including an ignition unit that causes an output current output by the current output unit to flow through the squib when an ignition signal is instructed;
The current output unit is
A current detector for detecting the current value of the output current;
A control unit for controlling the current value of the output current to a predetermined current value based on the current value detected by the current detection unit,
The airbag ignition circuit according to claim 1, wherein the ignition unit includes a current limiting unit that limits a current flowing through the squib to less than a predetermined second current value. An ignition number generator for generating the number of squibs that are ignited simultaneously in the same time period;
The current output unit is a current value obtained by multiplying a predetermined second current value by a number obtained by subtracting 1 from the number generated by the ignition number generating unit, and a current value less than the predetermined second current value. The airbag ignition circuit according to claim 1, wherein a value obtained by adding a predetermined third current value is set as the predetermined current value. The current output unit further includes a voltage detection unit that detects an output voltage,
The airbag control circuit according to claim 2, wherein the control unit controls the output voltage to be less than a predetermined voltage based on the output voltage detected by the voltage detection unit. A current value switching signal generation unit that generates a current value switching signal for switching a current value every time a predetermined time elapses when the voltage detection unit detects that the output voltage is equal to or higher than the predetermined voltage. Further including
4. The ignition number generation unit subtracts 1 from the number generated by the ignition number generation unit each time a current value switching signal is generated by a current value switching signal generation unit. Airbag ignition circuit. The current output unit outputs an output current and an output voltage from the time when a predetermined first delay time has elapsed from the time when the ignition signal is instructed to the time when the ignition signal is no longer instructed,
The ignition unit outputs the output current output from the current output unit to the squib from the time when the ignition signal is instructed to the time when the predetermined second delay time elapses from the time when the ignition signal is no longer instructed The airbag ignition circuit according to any one of claims 1 to 4, wherein the airbag ignition circuit is enabled. Detecting an acceleration of the vehicle, determining whether or not the vehicle has collided based on the detected acceleration, and when determining that the vehicle has collided, an ignition signal generating unit that generates an ignition signal;
And further comprising a safing signal generator for generating a safing signal when it is determined that the vehicle has collided based on the detected acceleration.
When the ignition signal is generated by the ignition signal generation circuit and the safing signal is generated by the safing signal generation circuit, the ignition unit causes the output current output by the current output unit to flow through the squib,
The airbag ignition according to any one of claims 1 to 5, wherein the current output unit outputs an output current and an output voltage when a safing signal is generated by a safing signal generation circuit. circuit. A current output unit, a control unit, a voltage detection unit, an ignition unit, and a control unit among the safing signal generation unit, the voltage detection unit, and the ignition unit included in the airbag ignition circuit according to claim 6;
Based on the safing signal generated by the safing signal generator, an output permission signal for permitting the output of the output current and output voltage by the current output unit, and a permission signal for permitting the ignition unit to ignite are generated. An integrated circuit device comprising a safing control unit and integrated.

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