Related to switch control circuit and igniter
A conventional ignition device of a gasoline vehicle includes an igniter that controls an ignition coil connected to a spark plug. The igniter includes a switch element, which is connected to the ignition coil, and a control circuit, which on-off controls the switch element in accordance with an ignition instruction signal provided from an engine control unit (ECU) (for example, refer to Patent Document 1). The switch element is on-off controlled so that the igniter generates high voltage, which is supplied to the spark plug, with the ignition coil.
The spark plug may not produce a spark in which case a misfire will occur. A misfire may affect engine rotation or the like. Thus, there is a need to detect a status of misfire.
It is an object of the present invention to provide a switch control circuit and an igniter that allow for misfire status detection.
A switch control circuit according to one aspect of the present disclosure is a switch control circuit that controls a switch element connected to a primary coil of an ignition coil in accordance with an ignition signal. The switch element includes a transistor and a protection element connected between a collector and gate of the transistor. The switch control circuit includes a status detection circuit that uses a voltage at a gate terminal controlling the transistor or a voltage corresponding to a collector current of the transistor as a detection voltage and generates a status detection signal corresponding to a change in the detection voltage.
An ignitor according to a further aspect of the present disclosure includes a switch element connected to a primary coil of an ignition coil and a switch control circuit that controls the switch element in accordance with an ignition signal. The switch element includes a transistor and a protection element connected between a collector and gate of the transistor. The switch control circuit includes a status detection circuit that uses a voltage at a gate terminal controlling the transistor or a voltage corresponding to a collector current of the transistor as a detection voltage and generates a status detection signal corresponding to a change in the detection voltage.
A switch control circuit according to a further aspect of the present disclosure is a switch control circuit that controls a switch element connected to a primary coil of an ignition coil in accordance with an ignition signal. The switch element includes a transistor and a protection element connected between a terminal, which is connected to the primary coil, and a control terminal of the transistor. A status detection circuit uses a collector voltage of the transistor as a detection voltage and generates a status detection signal corresponding to a change in the detection voltage.
An ignitor according to a further aspect of the present disclosure includes a switch element connected to a primary coil of an ignition coil and a switch control circuit that controls the switch element in accordance with an ignition signal. The switch element includes a transistor and a protection element connected between a terminal, which is connected to the primary coil, and a control terminal of the transistor. The switch control circuit includes a status detection circuit that uses a collector voltage of the transistor as a detection voltage and generates a status detection signal corresponding to a change in the detection voltage.
The aspects of the present disclosure allow for misfire status detection.
Embodiments and modified examples will hereafter be described with reference to the drawings. The embodiments and modified examples described below exemplify configurations and methods for embodying a technical concept and are not intended to limit the material, shape, structure, arrangement, dimensions, and the like of each component to the description. The embodiments and modified examples described below may undergo various modifications.
In the present specification, “a state in which member A is connected to member B” includes a case in which member A and member B are directly connected physically and a case in which member A and member B are indirectly connected by another member that does not affect the electric connection state.
Similarly, “a state in which member C is arranged between member A and member B” includes a case in which member A is directly connected to member C or member B is directly connected to member C and a case in which member A is indirectly connected to member C by another member that does not affect the electric connection state or member B is indirectly connected to member C by another member that does not affect the electric connection state.
A first embodiment will now be described.
As shown in
The igniter 4, which includes a switch control circuit 11 and a switch element 12, on-off controls a switch element 12 based on an ignition instruction signal IGT provided from an ECU 7. When the switch element 12 is turned on by the ignition instruction signal IGT, battery voltage VBAT is applied to the primary coil 2a of the ignition coil 2, and current I1 flowing to the primary coil 2a increases over time. When the switch element 12 is turned off by the ignition instruction signal IGT, the current I1 of the primary coil 2a is interrupted. In this case, primary voltage V1, which is proportional to the time derivative of the current I1, is generated at the primary coil 2a. Further, secondary voltage V2, which is the product of the primary voltage V1 and the turns ratio, is generated at the secondary coil 2b. With the secondary voltage V2 generated in this manner, the spark plug 6 produces a spark.
As shown in
The ignition instruction signal IGT from the ECU 7 is input to the signal input terminal T5. The igniter 4 outputs an ignition confirmation signal IGF from the signal output terminal T4.
The igniter 4 includes the switch control circuit 11, the switch element 12, a resistor R1, capacitors C1 and C2, and a resistor R2 and is modularized and accommodated in a single package.
A first terminal of the resistor R1 is connected to the high potential power terminal T1, and a second terminal of the resistor R1 is connected to a high potential power terminal P1 of the switch control circuit 11. A first terminal of the capacitor C1 is connected between the high potential power terminal T1 and the low potential power terminal T2. The capacitor C2 is connected between a second terminal of the resistor R1 and the low potential power terminal T2. The battery voltage VBAT is supplied via the resistor R1 as a high potential power voltage VDD to the switch control circuit 11. The switch control circuit 11 is actuated by the high potential power voltage VDD. The resistor R1, for example, reduces surge voltage superimposed on the battery voltage VBAT, and mitigates stress acting on the switch control circuit 11. The capacitor C1, for example, reduces noise (e.g., spike noise) superimposed on the battery voltage VBAT and stabilizes the high potential power voltage VDD. The capacitor C2, for example, functions as a bypass capacitor that stabilizes the high potential power voltage VDD.
The switch control circuit 11 includes an input terminal P5, which receives the ignition instruction signal IGT via the input terminal T5, and a signal output terminal P4, which outputs the ignition confirmation signal IGF. Further, the switch control circuit 11 includes an output terminal P6, which is connected to the switch element 12, input terminals P7 and P8, which are connected to the two terminal of the resistor R2, and a low potential power terminal P2, which is connected to the low potential power terminal T2.
The switch control circuit 11 includes an under voltage protection circuit 21, an over voltage protection circuit 22, a signal detection circuit 23, an over duty protection circuit 24, a gate driver 25, a status detection circuit 26, an over current protection circuit (current detection circuit) 27, and a signal output circuit 28.
The under voltage protection (BUVP: Battery Under Voltage Protection) circuit 21 compares a drive voltage VDD with a predetermined threshold value and outputs a detection signal K1 having a level corresponding to the comparison result. The threshold value of the under voltage protection circuit 21 is set, for example, in correspondence with a lower limit voltage of an operable voltage range of the switch control circuit 11. The over voltage protection (BOVP: Battery Over Voltage Protection) circuit 22 compares the drive voltage with a predetermined threshold voltage and outputs a detection signal K2 having a level corresponding to the comparison result. The threshold voltage of the over voltage protection circuit 22 is set, for example, in correspondence with an upper limit voltage of the operable voltage range of the switch control circuit 11.
The signal detection circuit (signal detector) 23 includes a filter circuit and a comparator. The signal detection circuit 23 detects the ignition instruction signal IGT from the ECU 7 and outputs a received signal Sdet. The over duty protection circuit 24 generates a control signal Si that is provided to the gate driver 25 from the received signal Sdet of the signal detection circuit 23, the detection signal K1 of the under voltage protection circuit 21, and the detection signal K2 of the over voltage protection circuit 22. Further, the over duty protection circuit 24 generates the control signal Si from the received signal Sdet so that the switch element 12 is not turned on over a predetermined duty protection time.
The gate driver (Gate Drive) 25 outputs a gate signal Sg from the control signal Si that turns on and off the switch element 12. The switch element 12 is formed by a single semiconductor chip including a transistor 31. The transistor 31 is, for example, an insulated gate bipolar transistor (IGBT). Terminals (C, G, and E) of the transistor 31 may be referred to as terminals of the semiconductor chip, or the switch element 12.
The gate signal Sg, which is output from the gate driver 25, is provided via the output terminal P6 to gate terminal G of the switch element 12. The over current protection circuit 27 detects the state of the collector current Ic (emitter current Ie) of the switch element 12 from a detection voltage (emitter voltage Ve) at a node between the emitter terminal E of the switch element 12 and the resistor R2 and generates a detection signal CE corresponding to the detection result. The gate driver 25 lowers the level of a voltage Vsg of the gate signal Sg based on the detection signal CE. This limits the collector current Ic to less than or equal to the upper limit.
The status detection circuit (Ignition Status Detector) 26 uses the voltage at the gate terminal G that controls the transistor 31 of the switch element 12 as a detection voltage and outputs a detection signal FE corresponding to the detection voltage. The gate terminal G is provided with the gate signal Sg from the gate driver 25. Accordingly, the status detection circuit 26 uses the voltage of the gate signal Sg (gate voltage Vsg) as the detection voltage, detects the ignition status of the spark plug 6 from the detection voltage, and outputs the detection signal FE. For example, the status detection circuit 26 outputs the detection signal FE at a high level in a case where the spark plug 6 produces a spark, that is, in a normal state in which normal ignition occurs, and outputs the detection signal FE at a low level in a case where the spark plug 6 does not produce a spark, that is, in a misfire state in which normal ignition does not occur.
The signal output (output logic) circuit 28 combines various types of signals including the detection signal CE of the overcurrent protection circuit 27 with the detection signal FE of the status detection circuit 26 to generate the ignition confirmation signal IGF and output the ignition confirmation signal IGF. The ignition confirmation signal IGF is provided via the signal output terminal P4 of the switch control circuit 11 and the signal output terminal T4 of the igniter 4 to the ECU 7.
The switch element 12 includes the transistor 31 and a protection element 32 and is integrated on a single semiconductor substrate manufactured through a high-voltage process.
The protection element 32 is arranged between the gate and collector of a power transistor for the purpose of protection from over voltage. The protection element 32 includes, for example, a diode that is anti-series-connected between the gate and collector of the transistor 31. The diode is, for example, a Zener diode. When the transistor 31 is turned off and the primary current I1 flowing to the primary coil 2a of the ignition coil 2 is interrupted, the back electromotive force of the primary coil 2a generates a high voltage at the collector terminal C of the switch element 12. When a voltage that is greater than or equal to the clamp voltage of the protection element 32 is applied between the gate and collector of the transistor 31, the protection element 32 turns on the transistor 31 and releases the energy accumulated in the primary coil 2a of the ignition coil 2 to protect the transistor 31. The protection element 32 improves the avalanche tolerance of the transistor 31.
The switch element 12 may include a protection element connected between the gate and emitter of the transistor 31. The protection element includes a diode (e.g., Zener diode) anti-series-connected between the gate and the emitter of the transistor 31 and clamps over voltage (e.g., surge noise or the like) between the gate and emitter at a predetermined voltage for the purpose of protection from over voltage.
The emitter terminal E of the switch element 12 is connected via the resistor R2 to the low potential power terminal T2.
As shown in
The status detection circuit 26 includes comparators 41 and 42, current sources 43 and 44, a capacitor C11, and a comparator 45.
The inverting input terminals of the comparators 41 and 42 are supplied with the gate signal Sg (gate voltage Vsg). The non-inverting input terminal of the comparator 41 is supplied with the reference voltage Vref1, and the non-inverting input terminal of the comparator 41 is supplied with the reference voltage Vref2. The reference voltages Vref1 and Vref2 are set in correspondence with a change in the voltage Vsg. The comparator 41 compares the gate voltage Vsg and the reference voltage Vref1 and outputs a signal S11 having a level that is in accordance with the comparison result. The comparator 42 compares the gate voltage Vsg and the reference voltage Vref2 and outputs a signal S12 having a level that is in accordance with the comparison result.
A first terminal of the current source 43 is connected to the power line VDD and supplied with the drive voltage VDD. The current source 43 corresponds to a “first current source.” A second terminal of the current source 43 is connected to a first terminal of the capacitor C11, and a second terminal of the capacitor C11 is connected to the ground line AGND. The current source 44 is connected in parallel to the capacitor C11. The current source 43 is activated or inactivated in response to the output signal S11 of the comparator 41. The activated current source 43 produces a flow of a predetermined current I11. The current I11 charges the capacitor C11 and increases a voltage V11 at the first terminal of the capacitor C11.
The current source 44 is activated or inactivated in response to the output signal S12 of the comparator 42. The current source 44 corresponds to a “second current source.” The activated current source 44 produces a flow of a predetermined current I12. The current I12 discharges the capacitor C11 and decreases the voltage V11 at the first terminal of the capacitor C11. The first terminal of the capacitor C11 is connected to the non-inverting terminal of the comparator 45, and the inverting terminal of the comparator 45 is supplied with a reference voltage Vref3. The comparator 45 compares the voltage V11 at the first terminal of the capacitor C11 with the reference voltage Vref3 and outputs the detection signal FE in accordance with the comparison result.
The signal output circuit 28 receives the detection signal FE, which is output from the comparator 45, and the detection signal CE, which is output from the overcurrent protection circuit 27 shown in
As shown in
As shown in
In this manner, in accordance with the status of the spark plug 6, the gate-emitter voltage VGE and the collector current Ic decrease differently, and the period during which the collector-emitter voltage Vce is maintained at a high level becomes different.
The status detection circuit 26 shown in
As shown in
The output signal S11 of the comparator 41 charges the capacitor C11, and the output signal S12 of the comparator 42 discharges the capacitor C11. Accordingly, the voltage V11 at the first terminal of the capacitor C11 corresponds to changes in the gate-emitter voltage VGE (the gate voltage Vsg) shown in
The upper part of
The lower part of
From time t1 to time t3, the voltage V11 is higher than the reference voltage Vref3. As a result, the comparator 45 outputs the detection signal FE at a low level. As the voltage V11 decreases and becomes lower than the reference voltage Vref3, the comparator 45 outputs the detection signal FE at a high level.
The signal output circuit 28 shown in
The ECU 7 shown in
In N cycle, during a period in which the ignition instruction signal IGT has a high level, the igniter 4 turns on the transistor 31 of the switch element 12. When the transistor 31 is turned on, the battery voltage VBAT is applied between the two terminals of the primary coil 2a, and the current flowing via the primary coil 2a and the transistor 31, namely, the collector current Ic of the transistor 31, increases over time.
The overcurrent protection circuit 27 shown in
When the ignition instruction signal IGT shifts to a low level, the igniter 4 turns off the transistor 31 and interrupts the collector current Ic, namely, the primary current of the primary coil 2a. In this case, the primary voltage V1, which is proportional to the time derivative of a current Ic, is generated at the primary coil 2a. Further, the secondary voltage V2, which is proportional to the primary voltage V1, is generated at the secondary coil 2b.
When a spark is produced in a normal manner, the gate-emitter voltage VGE (gate voltage Vsg) and the collector current Ic decrease within a short period. Thus, the status detection circuit 26 shown in
Next, in N+1 cycle, the igniter 4 turns on the transistor 31 of the switch element 12 during a period in which the ignition instruction signal IGT has a high level. The overcurrent protection circuit 27 shown in
When the ignition instruction signal IGT shifts to a low level, the igniter 4 turns off the transistor 31 and interrupts the collector current Ic, namely, the primary current of the primary coil 2a. When a spark is not produced, the collector current Ic and the gate-emitter voltage VGE decrease over a long period. The status detection circuit 26 shown in
As shown in
Igniter Package
As shown in
As shown in
The resistor R1 is connected between the mount portion B1 of the lead frame F1 and the lead frame F7. The capacitor C1 is connected between the mount portion B1 of the lead frame F1 and the mount portion B2 of the lead frame F2. The capacitor C1 is mounted closer to the lead portions T1 and T2 of the lead frames F1 and F2 than the resistor R1. Further, the capacitor C2 is connected between the mount portion B2 of the lead frame F2 and the lead frame F7. The capacitor C2 and the capacitor C1 are mounted on opposite sides of the resistor R1. The resistor R1 and the capacitors C1 and C2 are connected by, for example, an Ag paste, solder, or the like.
A switch control device 11 is mounted on the mount portion B2 of the lead frame F2, and the switch element 12 is mounted on the mount portion B6 of the lead frame F6. The switch control device 11 is an IC chip on which the switch control circuit 11 shown in
A gate pad PG and an emitter pad PE, which correspond to the gate terminal G and the emitter terminal E shown in
Pads P1, P2, P4, P5, P6, P7, and P8, which correspond to the terminals shown in
Wires W1, W2, W4, W5, W6, W7, and W8 are, for example, aluminum wires each having a diameter of, for example, 125 μm. Wire W9 is, for example, an aluminum wire having a diameter of, for example, 250 μm. Wire W9 has a resistance of several mΩ to several tens of mΩ for example, 5 mΩ. The resistance component of wire W9 functions as the resistor R2 shown in
Plan View
As shown in
Cross-Sectional Structure of Switch Element (Cell)
The switch element 12 includes an N+ buffer layer 62 and an N− epitaxial layer 63, which is formed on the upper surface of a P+ substrate 61, and the collector electrode PC, which is formed on the lower surface of the P+ substrate 61. The thickness from the lower surface of the P+ substrate 61 to the upper surface of the N− epitaxial layer 63 is, for example, 260 μm. The thickness of the P+ substrate 61 is, for example, 150 μm, and the total thickness of the N+ buffer layer 62 and the N− epitaxial layer 63 is, for example, 90 μm.
An N+ diffusion region 64 is formed on the upper surface of the N− epitaxial layer 63. P+ diffusion regions 65 are selectively formed in the N+ diffusion region 64. Further, a P++ diffusion region 66, which has a higher concentration than the P+ diffusion region 65, and an N++ diffusion region 67, which has a higher concentration than the N+ diffusion region 64, are selectively formed in the P+ diffusion regions 65.
A gate electrode 69 is arranged on the N+ diffusion region 64, which is sandwiched by the P+ diffusion regions 65, and the P+ diffusion regions 65 with a gate oxide film 68 located in between. Further, the gate electrode 69 is covered by an interlayer insulation film 70. The gate oxide film 68 is, for example, a silicon oxide film. The gate electrode 69 is formed from, for example, polysilicon. The interlayer insulation film 70 is, for example, a silicon oxide film, a titanium film, or a titanium film/titanium nitride film (Ti/TiN).
An emitter wire 71 is formed on the interlayer insulation film 70. The emitter wire 71 is formed from, for example, AlSiCu. The emitter wire 71 has a thickness of, for example, 4 μm. A protective layer 72 is formed on the emitter wire 71. The protective layer 72 is formed from, for example, a polyimide resin.
Cross-Sectional Structure of Switch Element (Peripheral Portion)
A P+ diffusion region 73 and an N+ diffusion region 74 are selectively formed on the N− epitaxial layer 63. An oxide film 75 is selectively formed on the N− epitaxial layer 63. The oxide film 75 is formed to be thick on the N− epitaxial layer 63 and thin on the P+ diffusion region 73.
A polysilicon layer 76 is formed on the oxide film 75. A silicon oxide film 77 is formed on the polysilicon layer 76. A gate finger 78 is connected to the polysilicon layer 76. The gate finger 78 also serves as the gate side electrode of the protection element 32 between the gate and electrode of the transistor 31.
An N region 76n and a P region 76p are alternately formed in the polysilicon layer 76. The N region 76n and the P region 76p form the protection element 32 between the gate and collector of the transistor 31 shown in
As described above, the present embodiment has the advantages described below.
(1-1) The status detection circuit 26 detects a status from the gate voltage Vsg and outputs the detection signal FE. Then, the signal output circuit 28 combines the detection signal FE of the status detection circuit 26 with another signal to generate the ignition confirmation signal IGF. The ignition confirmation signal IGF, which is combined in this manner, allows a defective spark (misfire) of the spark plug 6 to be easily found.
(1-2) The status detection circuit 26 outputs the ignition confirmation signal IGF from the signal output terminal P4. Accordingly, the detection results of a plurality of detection circuits can be output from the same signal output terminal P4, and enlargement of the igniter 4 is limited.
(1-3) The status detection circuit 26 charges and discharges the capacitor C11 based on the output signals S11 and S12 of the comparators 41 and 42, which compare the gate voltage Vsg with the reference voltages Vref1 and Vref2, and outputs the detection signal FE based on the charge voltage V11 of the capacitor C11. Accordingly, even if the gate voltage Vsg is fluctuated by noise or the like, erroneous operations caused by the noise can be avoided.
Modified examples of the first embodiment will now be described. In the description hereafter, same reference numerals are given to those components that are the same as the corresponding components of the first embodiment. Such components will not be described in detail.
As shown in
As shown in
As shown in
As shown in
As shown in
The voltage-dividing resistors R21 and R22 are connected between the output terminal P6 and the ground line AGND. Output nodes of the voltage-dividing resistors R21 and R22 are connected to non-inverting terminals of the comparators 41 and 42. The inverting input terminal of the comparator 41 is supplied with a threshold voltage Vth1 and the inverting input terminal of the comparator 42 is supplied with a threshold voltage Vth2. The output terminal of the comparator 41 is connected to the input terminal of the NAND circuit 112, and the output terminal of the comparator 42 is connected via the inverter circuit 111 to the NAND circuit 112. The output terminal of the NAND circuit 112 is connected via the inverter circuit 113 to the gate terminal of the transistor M21. The source terminal of the transistor M21 is connected to the ground line AGND, and the drain terminal of the transistor M21 is connected to an input node N21 of the charge-discharge circuit 120.
The charge-discharge circuit 120 includes a current source 121 and transistors Q1 to Q5. The transistors Q1 to Q3 are, for example, PNP transistors, and the transistors Q4 and Q5 are, for example, NPN transistors. The emitters of the transistors Q1 to Q3 are connected to the power line VDD. The collector of the transistor Q1 is connected to a first terminal of the current source 121, and a second terminal of the current source 121 is connected to the ground line AGND. The bases of the transistors Q2 and Q3 are connected to the base and collector of the transistor Q1. The transistors Q1, Q2, and Q3 form a current-mirror circuit. The transistors Q2 and Q3 are configured so that the amount of flowing current is the same as the transistor Q1.
The collectors of the transistors Q2 and Q3 are connected to the collectors of the transistors Q4 and Q5, and the emitters of the transistors Q4 and Q5 are connected to the ground line AGND. Further, the collector of the transistor Q5 (input node N21) is connected to the bases of the two transistors Q4 and Q5. An output node N22 between the transistor Q2 and the transistor Q4 is connected to the capacitor C11. The transistor Q4 includes, for example, a plurality of parallel-connected transistors and is configured to produce a flow of current that is an integer multiple of the flow of current produced by the transistor Q5.
The transistor M22 is connected in parallel to the capacitor C11, and the gate of the transistor M22 is provided with the received signal Sdet. The gate of the transistor M21 may be provided with various types of internal detection signals of the switch control circuit 11c or a signal combining various types of signals.
The output terminal of the comparator 45 is connected to the set terminal S of a flip-flop circuit 130, and the reset terminal R of the flip-flop circuit 130 is provided with the signal provided to the gate of the transistor M22, namely, the received signal Sdet. The flip-flop circuit 130 outputs the ignition confirmation signal IGF from the output terminal Q.
In the status detection circuit 26c, the charge-discharge circuit 120 charges the capacitor C11 while the transistor M21 is on and discharges the capacitor C11 while the transistor M21 is off. The detection signal FE of the comparator 45, which detects the voltage V11 of the capacitor C11, sets the flip-flop circuit 130 and outputs the ignition confirmation signal IGF, which is in accordance with the ignition status, from the output terminal Q of the flip-flop circuit 130. Further, the received signal Sdet provided to the gate of the transistor M22 turns on the transistor M22 to shift the voltage V11 of the capacitor C11 to a low level and reset the flip-flop circuit 130.
As shown in
The igniter 4a includes a switch element 12a, the switch control circuit 11, the resistor R1, the capacitors C1 and C2, and the resistor R2 and is modularized and accommodated in a single package. The switch control circuit 11 includes the under voltage protection circuit 21, the over voltage protection circuit 22, the signal detection circuit 23, the over duty protection circuit 24, the gate driver 25, the status detection circuit 26, the overcurrent protection circuit 27, and the signal output circuit 28.
The switch element 12a is formed by a single semiconductor chip including a transistor 31a. The transistor 31a is, for example, a SiC MOSFET. The protection element 32 is connected between the gate and drain of the transistor 31a. Terminals (S, G, and D) of the transistor 31a may be described as the terminals of the semiconductor chip, or the switch element 12a. The gate terminal of the transistor 31a is connected via a resistor to the output terminal P6 of the switch control circuit 11. The gate signal Sg, which is output from the gate driver 25, is provided via the output terminal P6 to the gate terminal G of the switch element 12a. The source terminal of the transistor 31a is connected to the resistor R2, and the drain terminal of the transistor 31a is connected via the output terminal T6 to the primary coil 2a of the ignition coil 2.
The igniter 4a on-off controls the switch element 12a based on the ignition instruction signal IGT provided from the ECU 7. By turning the switch element 12a on and off, the secondary voltage V2 generated at the secondary coil 2b of the ignition coil 2 produces a spark with the spark plug 6. The status detection circuit 26 of the switch control circuit 11 uses the voltage at the gate terminal G, which controls the transistor 31a of the switch element 12a, as a detection voltage and outputs the detection signal FE corresponding to the detection voltage. The signal output circuit 28 combines various types of signals including the detection signal CE of the overcurrent protection circuit 27 with the detection signal FE of the status detection circuit 26 to generate the ignition confirmation signal IGF and output the ignition confirmation signal IGF. The switch control circuit 11a of
In this manner, for example, in the igniter 4a with the switch element 12a including the transistor 31a, which is a SiC MOSFET, the ignition confirmation signal IGF allows a defective spark (misfire) of the spark plug 6 to be easily found in the same manner as the first embodiment.
A second embodiment will now be described.
In this embodiment, same reference numerals are given to those components that are the same as the corresponding components of the above embodiment.
As shown in
The igniter 201 includes the switch element 12, a switch control circuit 211, the resistor R1, the capacitors C1 and C2, and the resistor R2 and is modularized and accommodated in a single package.
The switch control circuit 211 includes the under voltage protection circuit 21, the over voltage protection circuit 22, the signal detection circuit 23, the over duty protection circuit 24, the gate driver 25, a status detection circuit 226, the overcurrent protection circuit 27, and the signal output circuit 28.
The status detection circuit (Ignition Status Detector) 226 uses the voltage corresponding to the collector current Ic of the transistor 31 of the switch element 12 as a detection voltage and outputs the detection signal FE in correspondence with a change in the detection voltage. The status detection circuit 226 of the present embodiment detects the ignition status of the spark plug 6 from the emitter current Ie (collector current Ic) flowing through the resistor R2 and outputs the detection signal FE. A first terminal of the resistor R2 is connected to the emitter of the switch element 12, and a second terminal of the resistor R2 is connected to the ground line AGND. Accordingly, the status detection circuit 226 detects the ignition status of the spark plug 6 from a voltage Ve at node N31 (detection node between switch element 12 and resistor R2) that changes in accordance with the collector current Ic. For example, the status detection circuit 226 outputs the detection signal FE at a high level in a case where the spark plug 6 produces a spark, that is, in a normal state in which normal ignition occurs, and outputs the detection signal FE at a low level in a case where the spark plug 6 does not produce a spark, that is, in a misfire state in which normal ignition does not occur.
As shown in
The inverting input terminals of the comparators 41 and 42 are connected to an input terminal P7 and supplied with the voltage Ve.
The non-inverting input terminal of the comparator 41 is supplied with the reference voltage Vref1, and the non-inverting input terminal of the comparator 42 is supplied with the reference voltage Vref2. The reference voltages Vref1 and Vref2 are set in correspondence with a change in the voltage Ve.
The comparator 41 compares the voltage Ve and the reference voltage Vref1 and outputs the signal S11 having a level that is in accordance with the comparison result. The comparator 42 compares the voltage Ve and the reference voltage Vref2 and outputs the signal S12 having a level that is in accordance with the comparison result.
The first terminal of the current source 43 is connected to the power line VDD and supplied with the drive voltage VDD. A second terminal of the current source 43 is connected to a first terminal of the capacitor C11, and a second terminal of the capacitor C11 is connected to the ground line AGND. The current source 44 is connected in parallel to the capacitor C11.
The current source 43 is activated or inactivated in response to the output signal S11 of the comparator 41. The activated current source 43 produces a flow of a predetermined current I11. The current I11 charges the capacitor C11 and increases the voltage V11 at the first terminal of the capacitor C11.
The current source 44 is activated or inactivated in response to the output signal S12 of the comparator 42. The activated current source 44 produces a flow of a predetermined current I12. The current I12 discharges the capacitor C11 and decreases the voltage V11 at the first terminal of the capacitor C11.
The first terminal of the capacitor C11 is connected to the non-inverting terminal of the comparator 45, and the inverting terminal of the comparator 45 is supplied with a reference voltage Vref3.
The comparator 45 compares the voltage V11 at the first terminal of the capacitor C11 with the reference voltage Vref3 and outputs the detection signal FE in accordance with the comparison result.
The signal output circuit 28 receives the detection signal FE, which is output from the comparator 45, and the detection signal CE, which is output from the overcurrent protection circuit 27 shown in
The clock signal CLK is, for example, a system clock or a signal obtained by frequency-dividing the system clock, and used to receive the ignition control signal or the like.
The signal output circuit is actuated in accordance with the clock signal CLK to output the ignition confirmation signal IGF, which combines the detection signals FE and CE.
As shown in
As shown in
In this manner, in accordance with the status of the spark plug 6, the gate-emitter voltage VGE (gate voltage Vsg) and the collector current Ic decrease differently, and the period during which the collector-emitter voltage Vce is maintained at a high level becomes different.
The status detection circuit 226 shown in
As shown in
The output signal S11 of the comparator 41 charges the capacitor C11, and the output signal S12 of the comparator 42 discharges the capacitor C11. Accordingly, the voltage V11 at the first terminal of the capacitor C11 corresponds to changes in the collector current Ic shown in
As shown in
As described above, the present embodiment has the advantages described below.
(2-1) The status detection circuit 226 detects the status based on the detection voltage Ve corresponding to the collector current Ic of the transistor 31 and outputs the detection signal FE. Then, the signal output circuit 28 combines the detection signal FE of the status detection circuit 26 with another signal to generate the ignition confirmation signal IGF. The ignition confirmation signal IGF, which is combined in this manner, allows the status of a spark of the spark plug 6 to be easily checked.
Modified examples of the second embodiment will now be described. In the description hereafter, same reference numerals are given to those components that are the same as the corresponding components of the first and second embodiments. Such components will not be described in detail.
As shown in
As shown in
Addition
As shown in
The igniter 201a includes the switch element 12a, the switch control circuit 211, the resistor R1, the capacitors C1 and C2, and the resistor R2 and is modularized and accommodated in a single package.
The switch control circuit 211 includes the under voltage protection circuit 21, the over voltage protection circuit 22, the signal detection circuit 23, the over duty protection circuit 24, the gate driver 25, the status detection circuit 226, the overcurrent protection circuit 27, and the signal output circuit 28.
The switch element 12a is formed by a single semiconductor chip including a transistor 31a. The transistor 31a is, for example, a SiC MOSFET. The status detection circuit 226 of the switch control circuit 211 uses a voltage Vs corresponding to a drain current Id of the transistor 31a of the switch element 12a as a detection voltage and outputs the detection signal FE corresponding to a change in the detection voltage. For example, the status detection circuit 226 detects the ignition status of the spark plug 6 from a source current Is (drain current Id) flowing through the resistor R2 and outputs the detection signal FE. The signal output circuit 28 combines various types of signals including the detection signal CE of the overcurrent protection circuit 27 with the detection signal FE of the status detection circuit 226 to generate the ignition confirmation signal IGF and output the ignition confirmation signal IGF. The switch control circuit 211a of
In this manner, for example, in the igniter 201a with the switch element 12a including the transistor 31a, which is a SiC MOSFET, the ignition confirmation signal IGF allows a defective spark (misfire) of the spark plug 6 to be easily found in the same manner as the second embodiment.
A third embodiment will now be described.
In this embodiment, same reference numerals are given to those components that are the same as the corresponding components of the above embodiments. Such components will not be described in detail.
As shown in
The igniter 301 includes the switch element 12, a switch control circuit 311, the resistor R1, the capacitors C1 and C2, the resistor R2, a resistor R31 and is modularized and accommodated in a single package.
The switch control circuit 311 includes the high potential power terminal P1, the low potential power terminal P2, the output terminal P4, the input terminal P5, the output terminal P6, the input terminals P7 and P8, and an input terminal P11. The switch control circuit 311 receives the ignition instruction signal IGT via the input terminal P5. The switch control circuit 311 outputs the ignition confirmation signal IGF from the output terminal P4. The switch control circuit 311 detects the emitter current Ie of the switch element 12 from the potential difference between the two terminals of the resistor R2 connected to the input terminals P7 and P8.
The input terminal P11 of the switch control circuit 311 is connected to a first terminal of the resistor R31, and a second terminal of the resistor R31 is connected to the collector terminal C of the switch element 12.
The switch control circuit 311 includes the under voltage protection circuit 21, the over voltage protection circuit 22, the signal detection circuit 23, the over duty protection circuit 24, the gate driver 25, a status detection circuit 326, the overcurrent protection circuit 27, and the signal output circuit 28.
The status detection circuit 326 is connected via the input terminal P11 to the first terminal of the resistor R31. That is, the status detection circuit 326 is connected via the resistor R31 to the collector terminal C of the switch element 12.
The status detection circuit 326 uses the voltage corresponding to a collector voltage Vc of the transistor 31 of the switch element 12 as a detection voltage Vc2 and outputs the detection signal FE in correspondence with a change in the detection voltage Vc2. The status detection circuit 326 of the present embodiment is connected via the resistor R31 to the collector terminal C of the switch element 12. Accordingly, the status detection circuit 326 receives a voltage that is proportional to the collector voltage Vc as the detection voltage Vc2. The resistor R31 is, for example, a high-voltage resistor. A plurality of series-connected resistors for voltages lower than the resistor R31 may be used.
The threshold voltage Vth1 corresponding to the detection voltage Vc2 is set for the status detection circuit 326. The status detection circuit 326 compares the detection voltage Vc2 and the threshold voltage Vth1 to detect the status of the spark plug 6. Then, the status detection circuit 326 outputs the detection signal FE having a level corresponding to the detected status. In the present embodiment, the status detection circuit 326 monitors the time during which the detection voltage Vc2 is exceeding the threshold voltage Vth1 and detects the status of the spark plug 6 in accordance with the time. Then, the status detection circuit 326 outputs the detection signal FE having a level corresponding to the detected status.
The signal output circuit 28 combines various types of signals including the detection signal CE of the overcurrent protection circuit 27 with the detection signal FE of the status detection circuit 326 to generate the ignition confirmation signal IGF and output the ignition confirmation signal IGF. The ignition confirmation signal IGF is provided via the signal output terminal P4 of the switch control circuit 11 and the signal output terminal T4 of the igniter 4 to the ECU 7.
The switch element 12 includes the transistor 31 and a protection element 32 and is integrated on a single semiconductor substrate manufactured through a high-voltage process. The protection element 32 functions as a voltage clamp element that clamps the voltage (emitter-collector voltage) applied to the transistor 31 to protect the transistor 31.
As shown in
The inverting input terminal of the comparator 41 is connected via the input terminal P11 to the resistor R31 of
The non-inverting input terminal of the comparator 41 is supplied with a reference voltage Vth1. The reference voltage Vth1 is set in correspondence with a change in the collector voltage Vc2. The comparator 41 compares the collector voltage Vc2 and the reference voltage Vth1 and outputs the signal S11 having a level that is in accordance with the comparison result.
The first terminal of the current source 43 is connected to the power line VDD and supplied with the drive voltage VDD. A second terminal of the current source 43 is connected to a first terminal of the capacitor C11, and a second terminal of the capacitor C11 is connected to the ground line AGND. The current source 44 is connected in parallel to the capacitor C11.
The current source 43 is activated or inactivated in response to the output signal S11 of the comparator 41. The activated current source 43 produces a flow of a predetermined current I11. The current I11 charges the capacitor C11 and increases the voltage V11 at the first terminal of the capacitor C11. The current source 44 produces the flow of the predetermined current I12. The current I12 discharges the capacitor C11 and decreases the voltage V11 at the first terminal of the capacitor C11.
The first terminal of the capacitor C11 is connected to the non-inverting terminal of the comparator 45, and the inverting terminal of the comparator 45 is supplied with a reference voltage Vref3. The comparator 45 compares the voltage V11 at the first terminal of the capacitor C11 with the reference voltage Vref3 and outputs the detection signal FE in accordance with the comparison result. The signal output circuit 28 is actuated in accordance with the clock signal CLK to output the ignition confirmation signal IGF, which combines the detection signal FE, which is output from the comparator 45, and the detection signal CE, which is output from the overcurrent protection circuit 27 of
As shown in
As shown in
In this manner, in accordance with the status of the spark plug 6, the collector voltage Vc (Vc2) is maintained at a high level. Further, the period during which the collector voltage Vc (Vc2) is maintained at a high level may be longer than the period during which the gate-emitter voltage VGE is maintained in a predetermined voltage range. Thus, status detection using the collector voltage Vc (Vc2) may be easier than when using the gate voltage Vsg.
The status detection circuit 326 of the present embodiment shown in
As shown in
The current source 43, which is activated by the output signal S11 of the comparator 41, charges the capacitor C11. The current source 44 discharges the capacitor C11. Accordingly, the voltage V11 at the first terminal of the capacitor C11 corresponds to changes in the collector voltage Vc (Vc2) shown in
The ECU 7 shown in
In each cycle, during a period in which the ignition instruction signal IGT has a high level, the igniter 301 turns on the transistor 31 of the switch element 12. When the transistor 31 is turned on, the battery voltage VBAT is applied between the two terminals of the primary coil 2a, and the current flowing via the primary coil 2a and the transistor 31, namely, the collector current Ic of the transistor 31 increases over time. The overcurrent protection circuit 27 shown in
When the ignition instruction signal IGT shifts to a low level, the igniter 301 turns off the transistor 31 and interrupts the collector current Ic, namely, the primary current of the primary coil 2a. In this case, the primary voltage V1, which is proportional to the time derivative of the current Ic, is generated at the primary coil 2a. Further, the secondary voltage V2, which is proportional to the primary voltage V1, is generated at the secondary coil 2b. When a spark is generated in a normal manner, the collector voltage Vc decreases within a short period. Thus, the status detection circuit 326 shown in
Next, in N+1 cycle, the igniter 301 turns on the transistor 31 of the switch element 12 during a period in which the ignition instruction signal IGT has a high level. Then, when the ignition instruction signal IGT shifts to a low level, the igniter 301 turns off the transistor 31 and interrupts the collector current Ic, namely, the primary current of the primary coil 2a.
When a spark is not produced in a normal manner, the collector voltage Vc (Vc2) decreases over a long period. The status detection circuit 326 shown in
Igniter Package
The outer appearance of the igniter 301 is the same as the igniter 4 of the first embodiment and therefore not illustrated.
The igniter 301 includes lead frames F11 to F16 and F21 to F24 and the encapsulation resin 51 that encapsulates parts of the lead frames F11 to F16 and F21 to F24 and components of the igniter 301.
The lead frames F11 to F16 and F21 to F24 may be formed from a conductive metal, for example, copper (Cu), a Cu alloy, nickel (Ni), a Ni alloy, 42 alloy, or the like. A Pd plating, an Ag plating, a Ni/Pd/Ag plating, or the like may be applied to the surface of each of the lead frames F11 to F16 and F21 to F24.
The encapsulation resin 51 may be an insulative resin, for example, epoxy resin. Further, the encapsulation resin 51 has a predetermined color (e.g., black).
The lead frames F11 to F16 include mount portions B11 to B16 and the lead portions T1 to T6 extending from the mount portions B11 to B16. The lead portions T1 to T6 correspond to the terminals of the igniter 301.
The resistor R1 is connected between the mount portion B11 of the lead frame F11 and the lead frame F21. The capacitor C1 is connected between the mount portion B11 of the lead frame F11 and the mount portion B12 of the lead frame F12. The capacitor C1 is mounted closer to the lead portion T1 of the lead frame F11 than the resistor R1. The capacitor C2 is connected between the mount portion B12 of the lead frame F12 and the lead frame F21. The capacitor C2 and the capacitor C1 are mounted on opposite sides of the resistor R1. The resistor R1 and the capacitors C1 and C2 are connected to the lead frames by, for example, an Ag paste, solder, or the like.
A switch control device 311 is mounted on the mount portion B12 of the lead frame F12. The switch control device 311 is an IC chip (semiconductor device) that integrates the elements of the switch control circuit 311 shown in
The switch element 12 is mounted on the mount portion B16 of the lead frame F16. The switch element 12 is connected to the lead frame F16 by, for example, an Ag paste, solder, or the like. The lower surface of the switch element 12 includes the collector electrode PC, and the collector electrode PC is connected to the lead frame F16.
The resistor R31 is connected between the mount portion B16 of the lead frame F16 and the lead frame F24. the resistor R31 is connected to the lead frames by, for example, an Ag paste, solder, or the like. The lead frame F24 is connected by wire W11 to a pad P11 of the switch control device 311.
A chip component 331 is connected between the mount portion B12 of the lead frame F12 and the lead frame F22. The chip component 331 is connected to the lead frames by, for example, an Ag paste, solder, or the like. The lead frame F22 is connected by wire W12 to the switch control device 311. The chip component 331 is an external circuit component of the switch control device 311 and may be, for example, a capacitor, a resistor, or the like. The chip component 331 and wire W12 may be omitted in accordance with the configuration and function of the switch control device 311.
The gate pad PG and the emitter pad PE are exposed from the upper surface of the switch element 12.
Pads P1, P2, P4, P5, P6, P7, and P8 are exposed from the upper surface of the switch control device 311. Pad P1 is connected by wire W1 to lead frame F21. Pad P2 is connected by wire W2 to the mount portion B12 of the lead frame F12. Pad P4 is connected by wire W4 to the mount portion B14 of the lead frame F14. Pad P5 is connected by wire W5 to the mount portion B15 of the lead frame F15. Pad P6 is connected by wire W6 to the gate pad PG of the switch element 12. Pad P7 is connected by wire W7 to lead frame F23. The emitter pad PE of the switch element 12 is connected by wire W9a to the lead frame F23. The lead frame F23 is connected by wire W9b to the mount portion B2 of the lead frame F2 of the lead frame F12.
Wires W1, W2, W4, W5, W6, W7, and W8 are, for example, aluminum wires each having a diameter of, for example, 125 μm.
Wires W9a and W9b are, for example, aluminum wires each having a diameter of, for example, 250 μm. Wire W9b has a resistance of several mΩ to several tens of mΩ for example, 5 mΩ. The resistance component of wire W9b functions as the resistor R2 shown in
Structure of High-Voltage Resistor
As shown in
The switch element 12 is mounted on the mount portion B16 of the lead frame F16 and arranged with the gate pad PG directed toward the switch control device 311. Such mounting allows wire W6, which connects pad P6 of the switch control device 311 and the gate pad PG of the switch element 12, to be shortened.
As described above, the present embodiment has the advantages described below.
(3-1) The status detection circuit 326 detects the status from the collector voltage Vc (Vc2) and outputs the detection signal FE. Then, the signal output circuit 28 combines the detection signal FE of the status detection circuit 26 with another signal to generate the ignition confirmation signal IGF. The ignition confirmation signal IGF, which is combined in this manner, allows a defective spark (misfire) of the spark plug 6 to be easily found.
(3-2) The resistor R31, which is connected between the collector terminal C of the switch element 12 and the input terminal P11 of the switch control circuit 311, and the resistor R32, which is included in the switch control circuit 311, serve as voltage-dividing resistors to generate the collector voltage Vc2 that is proportional to the collector voltage Vc. The resistor R31 is a high-voltage resistor. Accordingly, the collector voltage Vc2, which can be input to the switch control circuit 311, is easily generated in proportion with the collector voltage Vc. Thus, the collector voltage Vc allows the status of the spark plug 6 to be easily checked.
Modified examples of the third embodiment will now be described. In the description hereafter, same reference numerals are given to those components that are the same as the corresponding components of the first to third embodiments. Such components will not be described in detail.
As shown in
As shown in
As shown in
As shown in
As shown in
The resistor R32 is connected via the input terminal P11 to the non-inverting terminal of the comparator 41 and one end of the resistor R32. The other end of the resistor R32 is connected to the ground line AGND. The inverting input terminal of the comparator 41 is supplied with the reference voltage Vth1. The output terminal of the comparator 41 is connected to the gate terminal of the transistor M21. The source terminal of the transistor M21 is connected to the ground line AGND, and the drain terminal of the transistor M21 is connected to the input node N21 of the charge-discharge circuit 120.
The charge-discharge circuit 120 includes a current source 121 and transistors Q1 to Q5. The transistors Q1 to Q3 are, for example, PNP transistors, and the transistors Q4 and Q5 are, for example, NPN transistors. The emitters of the transistors Q1 to Q3 are connected to the power line VDD. The collector of the transistor Q1 is connected to the first terminal of the current source 121, and the second terminal of the current source 121 is connected to the ground line AGND. The bases of the transistors Q2 and Q3 are connected to the base and collector of the transistor Q1. The transistors Q1, Q2, and Q3 form a current-mirror circuit. The transistors Q2 and Q3 are configured so that the amount of flowing current is the same as the transistor Q1.
The collectors of the transistors Q2 and Q3 are connected to the collectors of the transistors Q4 and Q5, and the emitters of the transistors Q4 and Q5 are connected to the ground line AGND. Further, the collector of the transistor Q5 (input node N21) is connected to the bases of the two transistors Q4 and Q5. The output node N22 between the transistor Q2 and the transistor Q4 is connected to the capacitor C11. The transistor Q4 includes, for example, a plurality of parallel-connected transistors and is configured to produce a flow of current that is an integer multiple of the flow of current produced by the transistor Q5.
The transistor M22 is connected in parallel to the capacitor C11, and the gate of the transistor M22 is provided with the received signal Sdet. The gate of the transistor M21 may be provided with various types of internal detection signals of the switch control circuit 311c or a signal combining various types of signals.
The output terminal of the comparator 45 is connected to the set terminal S of a flip-flop circuit 130, and the reset terminal R of the flip-flop circuit 130 is provided with the signal provided to the gate of the transistor M22, namely, the received signal Sdet. The flip-flop circuit 130 outputs the ignition confirmation signal IGF from the output terminal Q.
In the status detection circuit 326c, the charge-discharge circuit 120 charges the capacitor C11 while the transistor M21 is on and discharges the capacitor C11 while the transistor M21 is off. The detection signal FE of the comparator 45, which detects the voltage V11 of the capacitor C11, sets the flip-flop circuit 130 and outputs the ignition confirmation signal IGF, which is in accordance with the ignition status, from the output terminal Q of the flip-flop circuit 130. Further, the received signal Sdet provided to the gate of the transistor M22 turns on the transistor M22 to shift the voltage V11 of the capacitor C11 to a low level and reset the flip-flop circuit 130.
As shown in
The igniter 301b includes the switch element 12a, the switch control circuit 311, the resistor R1, the capacitors C1 and C2, and the resistor R2 and R31 and is modularized and accommodated in a single package. The switch control circuit 311 includes the under voltage protection circuit 21, the over voltage protection circuit 22, the signal detection circuit 23, the over duty protection circuit 24, the gate driver 25, a status detection circuit 326, the overcurrent protection circuit 27, and the signal output circuit 28.
The switch element 12a is formed by a single semiconductor chip including a transistor 31a. The transistor 31a is, for example, a SiC MOSFET. The protection element 32 is connected between the gate and drain of the transistor 31a. Terminals (S, G, and D) of the transistor 31a may be described as the terminals of the semiconductor chip, or the switch element 12a. The gate terminal of the transistor 31a is connected via a resistor to the output terminal P6 of the switch control circuit 311. The gate signal Sg, which is output from the gate driver 25, is provided via the output terminal P6 to the gate terminal G of the switch element 12a. The source terminal of the transistor 31a is connected to the resistor R2, and the drain terminal of the transistor 31a is connected via the output terminal T6 to the primary coil 2a of the ignition coil 2.
The igniter 301b on-off controls the switch element 12a based on the ignition instruction signal IGT provided from the ECU 7. By turning the switch element 12a on and off, the secondary voltage V2 generated at the secondary coil 2b of the ignition coil 2 produces a spark with the spark plug 6. The status detection circuit 326 of the switch control circuit 311 uses the collector voltage Vc of the switch element 12a (transistor 31a) as a detection voltage and outputs the detection signal FE corresponding to the detection voltage. The signal output circuit 28 combines various types of signals including the detection signal CE of the overcurrent protection circuit 27 with the detection signal FE of the status detection circuit 326 to generate the ignition confirmation signal IGF and output the ignition confirmation signal IGF. The switch control circuits 311a, 311b, 311c, and the like described above may be used as the switch control circuit 311.
In this manner, for example, in the igniter 301b with the switch element 12a including the transistor 31a, which is a SiC MOSFET, the ignition confirmation signal IGF allows a defective spark (misfire) of the spark plug 6 to be easily found in the same manner as the first embodiment.
A fourth embodiment will now be described.
In this embodiment, same reference numerals are given to those components that are the same as the corresponding components of the above embodiments. Such components will not be described in detail.
As shown in
The igniter 401 includes the switch element 12, a switch control circuit 411, the resistor R1, the capacitors C1 and C2, and the resistor R2 and is modularized and accommodated in a single package.
The switch element 12 includes the transistor 31 and the protection element 32 and is integrated on a single semiconductor substrate manufactured through a high-voltage process.
The switch control circuit 411 includes the high potential power terminal P1, the low potential power terminal P2, the output terminal P4, the input terminal P5, the output terminal P6, the input terminals P7 and P8, and the input terminal P11. The switch control circuit 411 receives the ignition instruction signal IGT via the input terminal P5. The switch control circuit 411 outputs the ignition confirmation signal IGF from the output terminal P4. The switch control circuit 411 detects the emitter current Ie of the switch element 12 from the potential difference between the two terminals of the resistor R2 connected to the input terminals P7 and P8.
The input terminal P11 of the switch control circuit 411 is connected to the first terminal of the resistor R31, and the second terminal of the resistor R31 is connected to the collector terminal C of the switch element 12.
The switch control circuit 411 includes the under voltage protection circuit 21, the over voltage protection circuit 22, the signal detection circuit 23, the over duty protection circuit 24, the gate driver 25, the overcurrent protection circuit 27, and a protection circuit 420.
The protection circuit 420 is connected between the input terminal P5 and the low potential power terminal P2. The switch control circuit 411 of the present embodiment includes a signal line LS5, which is connected to the input terminal P5 and which transmits the ignition instruction signal IGT, and the ground line AGND, which is connected to the low potential power terminal P2 that is connected to the low potential power terminal T2. In other words, the protection circuit 420 is connected between the signal line LS5 and the ground line AGND.
The protection circuit 420 protects internal circuits in stages subsequent to the protection circuit 420 from various types of noise superimposed on the signal line LS5 and the ground line AGND by the input terminal P5 and the low potential power terminal P2.
The protection circuit 420 of the present embodiment includes two protection elements 421 and 422 that are connected in series between the terminals P5 and P2. The protection elements 421 and 422 are diode elements. The protection element 421 corresponds to “the first diode element,” and the protection element 422 corresponds to “the second diode element.” In detail, a first terminal of the protection element 421 (corresponding to anode terminal of diode element) is connected to the signal line LS5, a second terminal of the protection element 421 (corresponding to cathode terminal) is connected to a second terminal of the protection element 422 (corresponding to cathode terminal), and a first terminal of the protection element 422 (corresponding to anode terminal) is connected to the ground line AGND. Thus, the protection circuit 420 is a circuit having an anti-series-connected bidirectional diode configuration. In the present specification, the diode element is an element functioning as a diode through wire-connection to a terminal.
In the present embodiment, the protection elements 421 and 422 are each formed by a P-channel Metal Oxide Semiconductor Field Effect Transistor (P-channel MOSFET). With a P-channel MOSFET, the source and back gate are connected to each other and function as the cathode terminal of the diode element. The drain of the P-channel MOSFET functions as the anode terminal of the diode element.
Example of Configuration of Protection Circuit
The protection circuit 420 includes the two protection elements 421 and 422 connected between the input terminal P5 and a ground terminal P2.
The protection elements 421 and 422 are each formed on a P-type semiconductor substrate (P-sub) 431. An N-type epitaxial layer (N-Epi) 432 is formed on the P-type semiconductor substrate 431. The N-type epitaxial layer 432 define a region forming a single element through element isolation by a P-type region 433 and a P+ region 434. The N-type epitaxial layer 432 includes an N-well 435, and the N-well 435 includes an N+ region 436, which becomes a back gate terminal BG, and a P+ region 437, which becomes a source terminal S, at the two sides of the N+ region 436. A P region 438 and a P+ region 439, which become a drain, are formed through double diffusion at two sides of the N-well 435 spaced apart from the N-well 435. An oxide film 440 and a field oxide film 441 are formed on the upper surface of the N-type epitaxial layer 432. A gate electrode 442 (gate terminal G) is formed on the upper surface of the oxide film 440.
The drain terminal D (P+ region 439) of the protection element 421 is connected to the signal line LS5, which leads to the input terminal P5. The source terminal S (P+ region 437), the back gate terminal BG (the N+ region 436), and the gate terminal G (the gate electrode 442) of the protection element 421 are connected to one another and to line L41. Line L41 is connected to the source terminal S, the back gate terminal BG, and the gate terminal G of the protection element 422. The drain terminal D of the protection element 422 is connected to the ground line AGND, which leads to the ground terminal P2. The ground terminal P2 is connected to each of the protection elements 421 and 422 of the P-type semiconductor substrate 431.
The protection circuit 420 includes the two protection elements 421 and 422 connected between the input terminal P5 and the ground terminal P2.
The protection elements 421 and 422 each include the P-channel MOSFET Q1, the parasitic transistor Q2 (illustrated as diode) connected between the source and drain of the P-channel MOSFET Q1, resistors R41 and R42 respectively connected to the source and the drain, and parasitic transistors Q13 and Q14 connected in series to the resistors R41 and R42. The parasitic transistor Q2 is an NPN transistor formed by a P+ region that becomes the drain terminal D, the N-type epitaxial layer 432, the N-well 435, and the P+ region 437 that becomes the source terminal S, which are shown in
Operation of Protection Circuit
In
When a positive surge voltage is applied, current flows from the input terminal P5 via the signal line LS5, the drain terminal D of the protection element 421, the source terminal S of the protection element 421, line L41, the source terminal S of the protection element 422, the drain terminal D of the protection element 422, and the ground line AGND to the ground terminal P2. In this case, voltage fluctuation at the signal line LS5, which leads to the input terminal P5, is clamped at the voltage of the sum (VF+ BVdss) of a forward voltage VF of the parasitic transistor Q2 of the protection element 421 and a reverse voltage (breakdown voltage) BVdss of a diode formed by the PMOS transistor Q1 of the protection element 422.
When a negative surge voltage is applied, current flows from the ground terminal P2 via the ground line AGND, the drain terminal D of the protection element 422, the source terminal S of the protection element 422, line L41, the source terminal S of the protection element 421, the drain terminal D of the protection element 421, and the signal line LS5 to the input terminal P5. Further, current flows from the ground terminal P2 across the protection element 421, that is, via the parasitic transistor Q3 (P-type semiconductor substrate 431, N-type epitaxial layer 432, and P region 438), and the P+ region 439, to the signal line LS5. The current flowing across the protection element 421 is limited to a subtle current (e.g., several mA) by the resistor component (e.g., resistor R41 shown in
Igniter Package
The igniter 401 includes the lead frames F1 to F7 and the encapsulation resin 51 that encapsulates parts of the lead frames F1 to F7 and components of the igniter 401.
The lead frames F1 to F7 may be formed from a conductive metal, for example, Cu, a Cu alloy, Ni, a Ni alloy, 42 alloy, or the like. A Pd plating, an Ag plating, a Ni/Pd/Ag plating, or the like may be applied to the surface of each of the lead frames F1 to F7. The encapsulation resin 51 may be an insulative resin, for example, epoxy resin. Further, the encapsulation resin 51 has a predetermined color (e.g., black).
The lead frames F1 to F6 include the mount portions B1 to B6 and lead portions T1 to T6 extending from the mount portions B1 to B6. The lead portions T1 to T6 correspond to the terminals of the igniter 4.
The resistor R1 is connected between the mount portion B1 of the lead frame F1 and the lead frame F7. The capacitor C1 is connected between the mount portion B1 of the lead frame F1 and the mount portion B2 of the lead frame F2. The capacitor C1 is mounted closer to the lead portions T1 and T2 of the lead frames F1 and F2 than the resistor R1. Further, the capacitor C2 is connected between the mount portion B2 of the lead frame F2 and the lead frame F7. The capacitor C2 and the capacitor C1 are mounted on opposite sides of the resistor R1. The resistor R1 and the capacitors C1 and C2 are connected by, for example, an Ag paste, solder, or the like.
A switch control device 11 is mounted on the mount portion B2 of the lead frame F2, and the switch element 12 is mounted on the mount portion B6 of the lead frame F6. The switch control device 11 is an IC chip on which the switch control circuit 11 shown in
The gate pad PG and the emitter pad PE are exposed from the upper surface of the switch element 12. Pads P1, P2, P4, P5, P6, P7, and P8 are exposed from the upper surface of the switch control device 11. Pad P1 is connected by wire W1 to the lead frame F7. Pad P2 is connected by wire W2 to the mount portion B2 of the lead frame F2. Pad P5 is connected by wire W5 to the mount portion B5 of the lead frame F5. Pad P6 is connected by wire W6 to the gate pad PG of the switch element 12. Pad P7 is connected by wire W7 to the emitter pad PE of the switch element 12. The emitter pad PE of the switch element 12 is connected by wire W9 to the mount portion B2 of the lead frame F2. Pad P8 of the switch control device 11 is connected by wire W8 to the mount portion B2 of the lead frame F2. Wires W1, W2, W5, W6, W7, and W8 are, for example, aluminum wires each having a diameter of, for example, 125 μm. Wire W9 is, for example, an aluminum wire having a diameter of, for example, 250 μm. Wire W9 has a resistance of several mΩ to several tens of mΩ, for example, 5 mΩ. The resistance component of wire W9 functions as the resistor R2 shown in
Layout of Switch Control Circuit
The switch control circuit 411 includes a semiconductor substrate 450. Pads P1, P2, P5, P6, P7, and P8, which correspond to the terminals shown in
Pad P1, pad P7, and pad P8 are arranged on a Y1-direction end of the semiconductor substrate 450. Pad P1 is arranged on an X2-direction end and has a longer dimension in the X direction than the Y direction. Pad P7 is arranged proximate to the X1-direction end and has a Y-direction dimension Y6 that is longer than an X-direction dimension X6. Pad P8 is arranged proximate to the central part with respect to the X direction and has a Y-direction dimension Y7 that is longer than an X-direction dimension X7. Pad P7 and pad P8 respectively correspond to “the first pad” and “the second pad” of the present invention. Pads P2 and P5 are arranged on a Y2-direction end of the semiconductor substrate 450. Pad P2 is arranged on an X2-direction end and has a longer dimension in the Y direction than the X direction. Pad P5 is arranged proximate to the X1-direction end and has a longer dimension in the Y direction than the X direction. Pad P6 is arranged at the Y2 side of pad P7 in the X1 direction and has a longer dimension in the X direction than the Y direction. Pads P1, P2, and P5 to P8 are shaped in correspondence to the direction in which bonding wires are bonded.
The semiconductor substrate 450 includes a plurality of regions 451, 452, 453, and 454. Region 451 is where functional elements of the circuits 21 to 25 and 27 of the switch control circuit 411 are formed. Region 452 is where the protection elements 421 and 422 of the protection circuit 420 are formed. Region 453 is where a protection circuit, which protects the switch control circuit 411 from a surge or noise received from pads P1 and P2, is formed. Region 454 is where a test pad is formed. The IC chip layout of the switch control circuit 411 is not limited to that shown in
Schematic Plan View of Protection Element
The protection elements 421 and 422 include the semiconductor substrate 450 and a plurality of gate electrodes 442 formed on the semiconductor substrate 450. The gate electrodes 442 extend in a predetermined direction (vertical direction in
One of the regions sandwiching the gate electrode 442 is an N-well region 435 and the other one is a drain region 439. A source contact 463 and a back gate contact 464 are alternately arranged in the N-well region 435. A drain contact 465 is arranged in the drain region 439. The source contact 463 is connected to the P+ region 437 (not shown), which has substantially the same size as the source contact 463. Each back gate contact 464 is surrounded by an N+ region 436.
The operation of the protection circuit 420 in the present embodiment will now be described.
The protection circuit 420, which has a bi-directional diode structure, includes the protection elements 421 and 422. The protection elements 421 and 422 each have a PMOSFET structure that is a diode element connecting the source terminal S of the PMOSFET to the gate terminal G and the back gate terminal BG. The anode terminals of the protection elements 421 and 422 are connected to the signal line LS5 that leads to the input terminal P5, the ground line AGND that leads to the ground terminal P2. Further, the cathode terminals of the protection elements 421 and 422 are connected to each other. The protection circuit 420 including the protection elements 421 and 422 that are configured and connected as described above limits damage inflicted by surge to the protection elements 421 and 422 and improves immunity.
A comparative example of the protection circuit 420 (the protection elements 421 and 422) of the present embodiment will now be described.
As a comparative example, for example, an NMOSFET can be diode-connected to form a protection element. However, there is a tendency of the characteristics varying between protective elements using NMOSFETs, and a protection element will have low surge resistance when its characteristics vary.
In the NMOSFET, parasitic NPN transistors Qa and Qb are formed between the N− region 502 and the N+ regions 503a and 503b, and the parasitic NPN transistors Qa and Qb are connected via a parasitic resistor, which is formed by the resistor components of the N− region 502 and the N+ region 504, to the contact 506c.
Such a displacement produces a difference in resistance between the contact 506c and the parasitic NPN transistors Qa and Qb. The sheet resistance of the N− region 502 is ten times or greater than the sheet resistance of the N+ region 504. Thus, the resistance between the collector of the parasitic NPN transistor Qb and the contact 506c is lower than the resistance between the collector of the parasitic transistor Qa and the contact 506c. This reduces the current-limiting effect. In this case, the current resulting from a surge may concentrate at a portion where the resistance is small, namely, the parasitic NPN transistor Qb, and thereby inflict damage.
The displacement in the NMOSFET may occur during a manufacturing process.
In the step shown in the upper section of
In the step shown in the middle section of
In the step shown in the lower section of
In this regard, the protection elements 421 and 422 of the protection circuit 420 in the present embodiment have PMOS configurations. This limits displacement such as that described above.
In the step shown in the upper section of
In the step shown in the middle section of
As described above, the present embodiment has the advantages described below.
(4-1) The protection circuit 420 includes the two protection elements 421 and 422 connected in series between the input terminal P5 and the low potential power terminal P2. The protection elements 421 and 422 are diode elements. The protection circuit 420 is a circuit having an anti-series-connected bidirectional diode configuration. The diode element is an element functioning as a diode through wire-connection to a terminal, and the protection elements 421 and 422 are formed by PMOSFETs. The protection circuit 420 including the protection elements 421 and 422 improve the immunity of the switch control circuit 411.
(4-2) The protection elements 421 and 422 are formed by PMOSFETs. In the manufacturing process of the PMOSFETs, the gate electrode 442 and the field oxide film 441 are used as a mask when forming the P+ regions 437 and 439, which become the source terminal S and the drain terminal D. Such a structure limits current concentration that would result from a surge and protects the protection elements 421 and 422 from damage.
Modified examples of the fourth embodiment will now be described. In the description hereafter, same reference numerals are given to those components that are the same as the corresponding components of the first to fourth embodiments. Such components will not be described in detail.
As shown in
The igniter 401a includes the switch element 12, the switch control circuit 411a, the resistor R1, the capacitors C1 and C2, and the resistor R2 and is modularized and accommodated in a single package.
The switch control circuit 411a includes the under voltage protection circuit 21, the over voltage protection circuit 22, the signal detection circuit 23, the over duty protection circuit 24, the gate driver 25, the overcurrent protection circuit 27, and a protection circuit 420a.
The protection circuit 420a is connected between the input terminal P5 and the low potential power terminal P2. The protection circuit 420a protects internal circuits in stages subsequent to the protection circuit 420a from various types of noise superimposed on the signal line LS5 and the ground line AGND by the input terminal P5 and the low potential power terminal P2.
The protection circuit 420a includes three protection elements 421, 422, and 423 connected in series between the terminals P5 and P2. The protection elements 421, 422, and 423 are diode elements. The protection element 421 corresponds to “the first diode element,” and the protection elements 422 and 423 correspond to “the second diode element.” Further, the protection elements 421, 422, and 423 are each formed by a PMOSFET.
A first terminal (corresponding to anode terminal) of the protection element 421 is connected to the signal line LS5, and a second terminal (corresponding to cathode terminal) of the protection element 421 is connected to a second terminal (corresponding to cathode terminal) of the protection element 422. A first terminal (corresponding to anode terminal) of the protection element 422 is connected to a second terminal (corresponding to cathode terminal) of the protection element 423, and a first terminal (corresponding to anode terminal) of the protection element 423 is connected to the ground line AGND. Thus, the protection circuit 420 is a circuit having a bidirectional diode configuration in which the two protection elements 422 and 423 are anti-series connected to the single protection element 421.
Example of Configuration of Protection Circuit
The protection circuit 420a includes the three protection elements 421, 422, and 423 connected between the input terminal P5 and the ground terminal P2.
The protection elements 421, 422, and 423 have the same structure as the fourth embodiment (
The drain terminal D of the protection element 421 is connected to the signal line LS5, which leads to the input terminal P5. The source terminal S, back gate terminal BG, and gate terminal G of the protection element 421 are connected to one another and to line L42, and line L42 is connected to the source terminal S, back gate terminal BG, and gate terminal G of the protection element 422. The drain terminal D of the protection element 422 is connected by line L43 to the source terminal S, back gate terminal BG, and gate terminal G of the protection element 423, and the drain terminal D of the protection element 423 is connected to the ground line AGND, which leads to the ground terminal P2. The ground terminal P2 is connected to the P-type semiconductor substrate 431 of each of the protection elements 421, 422, and 423.
The protection circuit 420a includes the three protection elements 421, 422, and 423 connected between the input terminal P5 and the ground terminal P2.
Each of the protection elements 421 to 423 includes the P-channel MOSFET Q1, the parasitic transistor (illustrated as diode) Q2 between the source and drain of the P-channel MOSFET Q1, resistors R41a and R41b respectively connected to the source and drain, and the parasitic transistors Q3 and Q4 connected in series to the resistors R41a and R41b.
Operation of Protection Circuit
In
When a positive surface voltage is applied, current flows from the input terminal P5 via the signal line LS5, the drain terminal D of the protection element 421, the source terminal S of the protection element 421, line L42, the source terminal S of the protection element 422, the drain terminal D of the protection element 422, line L43, the source terminal S of the protection element 423, the drain terminal D of the protection element 423, and the ground line AGND to the ground terminal P2. In this case, voltage fluctuation at line LS5, which leads to the input terminal P5, is clamped at the voltage of the sum (VF+2×BVdss) of the forward voltage VF of the parasitic transistor Q2 of the protection element 421 and the reverse voltage (breakdown voltage) of a diode formed by the PMOS transistor Q1 of the two protection elements 422 and 423.
When a negative surge voltage is applied, current flows from the ground terminal P2 via the ground line AGND, the drain terminal D of the protection element 423, the source terminal S of the protection element 423, line L43, the drain terminal D of the protection element 422, the source terminal S of the protection element 422, line L42, the source terminal S of the protection element 421, the drain terminal D of the protection element 421, and the signal line LS5 to the input terminal P5. Further, current flows from the ground terminal P2 across the protection element 421, that is, via the parasitic transistor Q3 to the signal line LS5. The current flowing across the protection element 421 is limited to a subtle current (e.g., several mA) by the resistor component of the N-type epitaxial layer 432 (resistor R41a shown in
As shown in
The igniter 401b includes the switch element 12a, the switch control circuit 411, the resistor R1, the capacitors C1 and C2, and the resistor R2 and is modularized and accommodated in a single package. The switch element 12a is formed by a single semiconductor chip including the transistor 31a, and the transistor 31a is, for example, a SiC MOSFET. In this manner, in the igniter 401b with the switch element 12a including the transistor 31a, which is a SiC MOSFET, damage is limited in the protection elements 421 and 422 of the protection circuit 420 and immunity is improved in the same manner as the fourth embodiment. The protection circuit 420 can also use the protection circuit 420a of
In the above embodiments and modified examples, IGBTs and SiC MOSFETs are used as transistors. However, GaN power devices or the like can also be used as transistors.
Each of the above embodiments and modified examples may be combined.
The technical ideas which can be recognized from each of the embodiments described above and each of the modified examples described above will now be described.
A switch control circuit that controls a switch element connected to a primary coil of an ignition coil in accordance with an ignition signal, wherein the switch element includes a transistor and a protection element connected between a collector and gate of the transistor, the switch control circuit comprising:
a status detection circuit that uses a voltage at a gate terminal controlling the transistor or a voltage corresponding to a collector current of the transistor as a detection voltage and generates a status detection signal corresponding to a change in the detection voltage.
The switch control circuit according to embodiment 1, wherein
the status detection circuit includes a first comparator that compares the detection voltage and a first reference voltage and a second comparator that compares the detection voltage and a second reference voltage, and
the status detection circuit generates the status detection signal based on output signals of the first comparator and the second comparator.
The switch control circuit according to embodiment 1 or 2, wherein the detection voltage corresponding to the collector current is a voltage at a terminal connected between an emitter of the transistor and a resistor connected to the emitter.
The switch control circuit according to embodiment 2, wherein the status detection circuit includes a capacitor, charges and discharges the capacitor with the output signals of the first comparator and the second comparator, and generates the status detection signal based on a charge voltage of the capacitor.
The switch control circuit according to any one of embodiments 1 to 4, comprising a signal output circuit that outputs the status detection signal to a terminal.
The switch control circuit according to any one of embodiments 1 to 4, comprising a signal output circuit that outputs an ignition confirmation signal based on the status detection signal.
The switch control circuit according to embodiment 5 or 6, comprising:
a current detection circuit that detects the collector current of the transistor,
wherein the signal output circuit combines a detection signal of the current detection circuit and a detection signal of the status detection circuit to generate an ignition confirmation signal.
The switch control circuit according to any one of embodiments 5 to 7, wherein the signal output circuit outputs the status detection signal at a time corresponding to the ignition signal.
The switch control circuit according to any one of embodiments 1 to 8, wherein the switch element includes a protection element connected between an emitter and gate of the transistor.
An ignitor, comprising:
a switch element connected to a primary coil of an ignition coil; and
a switch control circuit that controls the switch element in accordance with an ignition signal, wherein
the switch element includes a transistor and a protection element connected between a collector and gate of the transistor, and
the switch control circuit includes a status detection circuit that uses a voltage at a gate terminal controlling the transistor or a voltage corresponding to a collector current of the transistor as a detection voltage and generates a status detection signal corresponding to a change in the detection voltage.
A switch control circuit that controls a switch element connected to a primary coil of an ignition coil in accordance with an ignition signal, wherein the switch element includes a transistor and a protection element connected between a collector and gate of the transistor, the switch control circuit comprising:
a status detection circuit that uses a collector voltage of the transistor as a detection voltage and generates a status detection signal corresponding to a change in the detection voltage.
The switch control circuit according to embodiment 11, wherein the status detection circuit includes a second resistor that generates the detection voltage by voltage-dividing the collector voltage of the transistor with a first resistor connected to a collector terminal of the switch element.
The switch control circuit according to embodiment 11 or 12, wherein the status detection circuit includes a first comparator, which compares the detection voltage and a first reference voltage, and generates the status detection signal based on output signals of the first comparator.
The switch control circuit according to embodiment 13, wherein the status detection circuit includes
a capacitor,
a first current source that charges the capacitor based on the output signal of the first comparator,
a second current source that discharges the capacitor, and
a second comparator that compares a charge voltage of the capacitor and a second reference voltage to output the status detection signal.
The switch control circuit according to any one of embodiments 11 to 14, comprising a signal output circuit that outputs the status detection signal to a terminal.
The switch control circuit according to any one of embodiments 11 to 14, comprising a signal output circuit that outputs an ignition confirmation signal based on the status detection signal.
The switch control circuit according to embodiment 15 or 16, comprising:
a current detection circuit that detects a collector current of the transistor,
wherein the signal output circuit combines a detection signal of the current detection circuit and a detection signal of the status detection circuit to generate an ignition confirmation signal.
The switch control circuit according to any one of embodiments 15 to 17, wherein the signal output circuit outputs the status detection signal at a time corresponding to the ignition signal.
The switch control circuit according to any one of embodiments 11 to 18, wherein the switch element includes a protection element connected between an emitter and gate of the transistor.
An ignitor, comprising:
a switch element connected to a primary coil of an ignition coil; and
a switch control circuit that controls the switch element in accordance with an ignition signal, wherein
the switch element includes a transistor and a protection element connected between a terminal, which is connected to the primary coil, and a control terminal of the transistor, and
the switch control circuit includes a status detection circuit that uses a voltage corresponding to a collector voltage of the transistor as a detection voltage and generates a status detection signal corresponding to a change in the detection voltage.
A switch control circuit that controls a switch element connected to a primary coil of an ignition coil in accordance with an ignition signal, the switch control circuit comprising:
a protection circuit connected between an input terminal, which is provided with the ignition signal, and a ground terminal, which is connected to ground, wherein the protection circuit includes
one first diode element connected to the input terminal and arranged toward the ground terminal from the input terminal in a forward direction, and
at least one second diode element connected between the first diode element and the ground terminal and arranged toward the ground terminal from the input terminal in a reverse direction,
wherein the first diode element and the second diode element are each formed by a PMOSFET.
The switch control circuit according to embodiment 21, wherein the protection circuit includes two series-connected second diode elements.
The switch control circuit according to embodiment 21 or 22, wherein the protection circuit is formed on a semiconductor substrate on which the switch control circuit is integrated in a region between a first pad, to which the input terminal is connected, and a second pad, to which the ground terminal is connected.
The switch control circuit according to any one of embodiments 1 to 9 and 11 to 19, comprising:
a protection circuit connected between an input terminal, which is provided with the ignition signal, and a ground terminal, which is connected to ground, wherein the protection circuit includes
one first diode element connected to the input terminal and arranged toward the ground terminal from the input terminal in a forward direction, and
at least one second diode element connected between the first diode element and the ground terminal and arranged toward the ground terminal from the input terminal in a reverse direction,
wherein the first diode element and the second diode element are each formed by a PMOSFET.
The igniter according to embodiment 10 or 20, comprising:
a protection circuit connected between an input terminal, which is provided with the ignition signal, and a ground terminal, which is connected to ground, wherein the protection circuit includes
one first diode element connected to the input terminal and arranged toward the ground terminal from the input terminal in a forward direction, and
at least one second diode element connected between the first diode element and the ground terminal and arranged toward the ground terminal from the input terminal in a reverse direction,
wherein the first diode element and the second diode element are each formed by a PMOSFET.
4, 4a, 201, 201a, 301, 301a, 401, 401a, 401b) ignitor; 11, 11a to 11c, 211, 211a, 211b) switch control circuit; 26, 26c, 226, 326) status detection circuit; 12, 12a) switch element
Number | Date | Country | Kind |
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JP2018-045701 | Mar 2018 | JP | national |
JP2018-127728 | Jul 2018 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2019/006734 | 2/22/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/176501 | 9/19/2019 | WO | A |
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