JP2008286164A - Glow plug disconnection detection device and glow plug power supply control device with disconnection detection function - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a glow plug disconnection detection device suitable for the case of supplying power to a glow plug having a plurality of heater lead wires for supply a heater with power, or to the heater via the plurality of heater lead wires connected in parallel with a power supply terminal of heater of the glow plug, and also to provide a glow plug power supply control device provided with such a glow plug disconnection detection function. <P>SOLUTION: A GCU2 consists of: the glow plug power supply control device 40; and a glow plug disconnection wire-breaking detection device 60. The detection device 60 detects whether a heater 21 of a glow plug 20, and respective heater lead wires 23A, 23B and 23C, are disconnected for thr glow plug 20 in the state of supplying power to a heater 21 via the plurality of heater lead wires 23A, 23B and 23C. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention includes a glow plug disconnection detection device for detecting the presence or absence of a heater disconnection in a glow plug energization system in which a heater of a glow plug is energized through a plurality of heater lead wires, and such a glow plug disconnection detection device. The present invention relates to a glow plug energization control device with a disconnection detection function.

  In general, in a diesel engine, when the temperature of the outside air is low and cold, the temperature in the cylinder may not reach the fuel ignition temperature even if the air in the cylinder is compressed. For this reason, in an automobile or the like equipped with a diesel engine, the air in the cylinder is heated to a high temperature by a glow plug to assist engine startup. Specifically, the heater of the glow plug is energized through one heater lead wire to generate heat. In the above-described automobiles and the like, a glow plug disconnection detection device that detects the presence or absence of disconnection of a heater and a heater lead wire of a glow plug in such a glow plug energization system may be mounted. (For example, refer to Patent Document 1).

JP-A-4-81578

  In Patent Document 1, one heater lead wire is connected to a glow plug and energization from a power source is performed using one energization switch means (for example, a switch element such as an FET). A glow plug energization control system for energizing a plug is described. Further, a glow plug disconnection detection device capable of detecting disconnection of a glow plug heater and one heater lead wire is disclosed.

However, since the heater is energized using a plurality of heater lead wires due to the structure of the glow plug, there is a case where the glow plug has a structure in which a plurality of heater lead wires are extended. Or, if you want to use multiple heater leads, using multiple switch elements with a small current capacity makes it cheaper than using a single switch element with a large current capacity to control the energization of the glow plug. There is also.
In a glow plug having a plurality of heater lead wires, or when a plurality of heater lead wires are connected to the energization terminal of the glow plug, only one of the heater lead wires may be disconnected. In this case, even if some of the heater lead wires are disconnected, the energization between the power source and the heater is performed by the other heater lead wires, so that the energization to the glow plug (heater) can be temporarily ensured.
However, since the resistance due to the remaining heater lead wires is increased by the presence of the disconnected heater lead wire, there is a possibility that heat generation in the glow plug (heater) cannot be performed properly. On the other hand, since the current flowing through the remaining heater lead wires increases, the heater lead wires are likely to generate heat, and there is a possibility that the coating of the heater lead wires may be deteriorated, melted or further disconnected.

  The present invention has been made in view of such a situation, and through a glow plug having a plurality of heater lead wires for energizing the heater or through a plurality of heater lead wires connected in parallel to the energization terminals of the heaters of the glow plug. An object of the present invention is to provide a glow plug disconnection detection device suitable for energizing a heater. It is another object of the present invention to provide a glow plug energization control device with a disconnection detection function provided with such a glow plug disconnection detection device.

  The solution includes a heater that generates heat when energized and a glow plug having a plurality of heater lead wires electrically connected in parallel to one end of the heater, or a heater that generates heat when energized and electrically connected to one end of the heater. A glow plug having a current-carrying terminal, a plurality of heater lead wires electrically connected in parallel to the current-carrying terminal, and a current flowing from the power source through the plurality of heater lead wires to the heater of the glow plug. A glow plug disconnection detecting device for detecting the presence or absence of disconnection of the heater, for a glow plug energization control system comprising a glow plug energization control device including a plurality of energization switch means that are intermittent for each line, each heater Glow plug disconnection detection device having disconnection detection means for detecting the presence or absence of disconnection of a lead wire A.

  Since the glow plug disconnection detecting device of the present invention is provided with the disconnection detecting means for detecting the presence or absence of disconnection of each heater lead wire, the disconnection of each heater lead wire can be detected appropriately. Accordingly, it is possible to prompt appropriate processing for the disconnection of the heater lead wire, such as issuing a warning.

In addition, as a disconnection detection means, what has a several separate disconnection detection means corresponding to each heater lead wire is mentioned, for example. Further, there may be mentioned one having a single or a number of individual disconnection detecting means smaller than the number of heater lead wires and a switching means for switching the connection between the heater lead wires to be detected.
In addition to a heater composed of a single heating wire (for example, a heating coil), there are a plurality of heaters such as a self-control heater in which a heating coil and a control coil for controlling the current flowing therethrough are connected in series. Includes a heater in which heating wires (coils, etc.) are connected in series or in parallel.

  Furthermore, in the above-described glow plug disconnection detection device, the disconnection detection means includes a plurality of individual disconnection detection means for detecting the presence or absence of disconnection of the heater lead wires, one to one corresponding to each of the heater lead wires. It is preferable to have a glow plug disconnection detecting device.

  In the glow plug disconnection detection device of the present invention, the disconnection detection means has individual disconnection detection means corresponding to each heater lead wire in a one-to-one relationship. Therefore, by accumulating the results of the individual disconnection detection means. As compared with the case where one individual disconnection detecting means is switched and used, it is possible to easily grasp which heater lead wire is disconnected.

  Or it is a glow plug disconnection detection apparatus of Claim 1, Comprising: The said disconnection detection means is a single or less than the number of the heater lead wires, and the individual disconnection which detects the presence or absence of the disconnection of the said heater lead wire A glow plug disconnection detection device having detection means and switching means for switching the connection between the heater lead wires detected by the individual disconnection detection means is preferable.

  In the glow plug disconnection detection device of the present invention, the disconnection detection means has a switching means for switching the connection between the individual disconnection detection means and the heater lead wires. And the number of the individual disconnection detection means required when it is made to correspond one-to-one. Thereby, the glow plug disconnection detection device can be further downsized and inexpensive.

  4. The glow plug disconnection detecting device according to claim 2 or 3, wherein the individual disconnection detecting means conducts electricity from the power source to the heater of the glow plug through any of the energization switch means. It is preferable to use a glow plug disconnection detection device that detects the presence or absence of disconnection in the heater lead wire to be inspected or the heater when the heater is not inspected.

  By the way, when detecting whether or not the heater lead wire or the heater is disconnected, it is determined whether or not the heater lead wire or the heater to be inspected is disconnected during a period in which power is supplied from the power source to the glow plug (heater). It is also possible. In this case, the time when the disconnection can be detected is limited to, for example, a pre-glow period and an after-glow period when the engine is started, and there is a possibility that the detection of the heater lead wire or the disconnection in the heater cannot be performed properly. Moreover, in order to detect the heater lead wire or the disconnection of the heater, it is necessary to control the energization to the glow plug (heater).

On the other hand, in the glow plug disconnection detection device of the present invention, the presence or absence of disconnection in the heater lead wire to be inspected or the heater is detected by the individual disconnection detection means during the period when the power is not supplied from the power source to the heater of the glow plug. Therefore, it is possible to increase the degree of freedom of the time when disconnection can be detected.
Even in the pre-glow period, the after-glow period, etc., if the glow plug (heater) generates heat by, for example, duty control (PWM control), that is, if it is not energized continuously, it is energized. It is possible to detect the heater lead wire or the heater disconnection during a period in which no power is supplied between the periods.

  Further, in the above-described glow plug disconnection detection device, the individual disconnection detection means is an object to be inspected when power is not supplied from the power source to the heater of the glow plug through any of the energization switch means. When the heater lead wire and the heater are energized and the heater lead wire to be inspected or the heater is disconnected, the disconnection voltage generated in the heater lead wire, the heater lead wire to be inspected, and A glow plug disconnection detection device that detects the presence or absence of disconnection in the heater lead wire to be inspected or the heater depending on which non-disconnection voltage generated in the heater lead wire occurs when the heater is conducting. And good.

  In the glow plug disconnection detecting device of the present invention, the presence or absence of disconnection is detected by the individual disconnection detecting means for the heater lead wire or heater to be inspected depending on whether the disconnection voltage or non-disconnection voltage is generated. It is possible to easily determine whether or not the inspection object is disconnected.

  Furthermore, it is good to set it as the glow plug energization control apparatus with a disconnection detection function provided with the glow plug disconnection detection apparatus of any one of Claims 1-5, and the said glow plug energization control apparatus.

The glow plug energization control device with a disconnection detection function of the present invention is configured to include the aforementioned glow plug disconnection detection device and glow plug energization control device.
In this way, in addition to energizing the heater, a glow plug having a plurality of heater lead wires for energizing the heater, or a method for energizing the heater through a plurality of heater lead wires connected in parallel to the heater energizing terminals The detection of the disconnection of the heater or the heater lead wire can be appropriately performed.

  Hereinafter, embodiments and modifications of the present invention will be described with reference to the drawings.

(Embodiment)
A GCU (glow plug energization control device with disconnection detection function) 2 according to the present embodiment is mounted on a vehicle (not shown) equipped with a diesel engine, and includes a later-described glow plug energization control device 40 and a glow plug disconnection detection device 60. (See FIG. 1). The GCU 2 controls the energization of the glow plug 20 having the heater 21 and three heater lead wires 23A, 23B, 23C electrically connected in parallel to one end thereof, as well as the heater 21 and the heater lead wires 23A, 23B. , 23C is detected. That is, the GCU 2 forms a glow plug energization system 1 with a disconnection detection function with the glow plug 20. Further, in the glow plug energization system 1 with the disconnection detection function, the glow plug energization control device 40 and the glow plug 20 constitute a glow plug energization system 10 described later. The glow plug energization system 1 with a disconnection detection function is electrically connected to an engine control unit (ECU) 90 that controls the engine and the like.

First, the glow plug energization system 10 will be described.
The glow plug energization system 10 includes a glow plug 20 and a glow plug energization control device 40.
The glow plug 20 includes a heater 21 (resistance value Rh) that generates heat when energized, and three heater lead wires 23A, 23B, and 23C that are electrically connected in parallel to one end 21N of the heater 21. . The other end 21S of the heater 21 is grounded.

The glow plug energization control device 40 includes FETs 41A, 41B, 41C, switch circuits 42A, 42B, 42C, and a microcomputer 80. Among these, the microcomputer 80 has a known configuration such as a CPU, a ROM, and a RAM (not shown), and loads a program stored in the ROM or the like to the CPU to perform a predetermined operation, for example, drive of the switch circuit 42A or the like. In addition, driving of an individual disconnection detection circuit 61A, which will be described later, and communication with the ECU 90 are performed.
Further, the FETs 41A, 41B, and 41C allow the heater lead of the glow plug 20 to pass a current flowing from the battery 50 having a battery potential (for example, 15V) through the heater lead wires 23A, 23B, and 23C of the glow plug 20 to the heater lead wire. This is an energization switch means that is intermittently provided every 23A, 23B, and 23C.
Specifically, each of the FETs 41A, 41B, and 41C branches in parallel at the first connection point 52 of the connection wiring 51 extending from the battery 50, and is connected to each of the heater lead wires 23A, 23B, and 23C. 47A, 47B and 47C are provided. Each FET 41A, 41B, 41C is switched on and off by the switch circuits 42A, 42B, 42C.

Each of the switch circuits 42A, 42B, and 42C includes a transistor 43 and resistors 44 and 45, and is a circuit having substantially the same connection form.
Therefore, the description of the switch circuits 42A, 42B, and 42C will be described in detail on behalf of the switch circuit 42A, and the description of the switch circuits 42B and 42C will be omitted or simplified.

In the switch circuit 42A, the base terminal of the transistor 43 is connected to the first output unit 81 of the microcomputer 80, and the emitter terminal of the transistor 43 is grounded. The collector terminal of the transistor 43 is connected to the battery 50 via resistors 44 and 45 connected in series. A second connection point 46A between the resistor 44 and the resistor 45 is connected to the gate terminal of the FET 41A.
In the switch circuit 42A, when the glow energization signal sig11 output from the first output unit 81 of the microcomputer 80 is set to a high level, the transistor 43 is turned on, and a current flows through the transistor 43 through the resistor 45 and the resistor 44. As a result, a voltage drop occurs in the resistor 45, a potential difference is generated between the source terminal and the gate terminal of the FET 41A, and the FET 41A is turned on. As a result, current can flow from the battery 50 to the heater 21 through the connection wiring 47A, the FET 41A, and the heater lead wire 23A of the glow plug 20. If the first output unit 81 of the microcomputer 80 is set to a low level, the FET 41A can be turned off and the energization of the heater 21 can be stopped conversely.

  Similarly, in the switch circuit 42B, when the glow energization signal sig12 output from the second output unit 82 of the microcomputer 80 is set to the high level, the FET 41B is turned on, and the connection wiring 47B is connected in parallel with the above-described FET 41A and the like. A current can be passed to the heater 21 through the FET 41B and the heater lead wire 23B.

  Further, even in the switch circuit 42C, when the glow energization signal sig13 output from the third output unit 83 of the microcomputer 80 is set to a high level, the FET 41C is turned on, and the connection wiring 47C, A current can be passed to the heater 21 through the FET 41C and the heater lead wire 23C.

  Thus, in the glow plug energization control device 40, the FETs 41 </ b> A, 41 </ b> B, and 41 </ b> C are turned on / off by the microcomputer 80, thereby enabling energization control to the heater 21 in parallel through the heater lead wires 23 </ b> A, 23 </ b> B, 23 </ b> C. . In the present embodiment, in order to adjust the temperature of the heater 21 appropriately, each FET 41A, 41B, 41C may be turned on / off to perform PWM control (see FIG. 5A).

Next, the glow plug disconnection detection device 60 will be described.
The glow plug disconnection detection device 60 also includes a microcomputer 80. Further, as shown in FIGS. 1 to 4, the glow plug disconnection detection device 60 detects the presence or absence of disconnection in the heater 21 of the glow plug 20, and each of the three heater lead wires 23 </ b> A, 23 </ b> B, 23 </ b> C. A disconnection detection circuit 61 (disconnection detection means) for detecting the presence or absence of disconnection is provided.
In the present embodiment, the disconnection detection circuit 61 further includes three individual disconnection detection circuits 61A, 61B, and 61C (individual disconnection detection means) that correspond one-to-one with the three heater lead wires 23A, 23B, and 23C. ing. Specifically, the individual disconnection detection circuit 61A detects the presence or absence of disconnection of the heater lead wire 23A. The individual disconnection detection circuit 61B detects the presence or absence of disconnection of the heater lead wire 23B. The individual disconnection detection circuit 61C detects the presence or absence of disconnection of the heater lead wire 23C.

These individual disconnection detection circuits 61A, 61B, and 61C are all composed of transistors 62 and 63, a diode 64, and resistors 65, 66, and 67, and are all circuits having the same connection form.
Accordingly, the individual disconnection detection circuits 61A, 61B, and 61C will be described on behalf of the individual disconnection detection circuit 61A, and the individual disconnection detection circuits 61B and 61C will be described briefly.

As shown in FIG. 2, in the individual disconnection detection circuit 61A, the base terminal of the transistor 62 is connected to the fourth output unit 84 of the microcomputer 80, and the emitter terminal of the transistor 62 is grounded. The collector terminal of the transistor 62 is connected to the base terminal of the transistor 63 via the resistor 65. The collector terminal of the transistor 63 is grounded via a resistor 66 and a resistor 67 connected in series. On the other hand, the emitter terminal of the transistor 63 is connected to a detection power supply 55 having a reference potential Vcc (for example, 5 V).
In the individual disconnection detection circuit 61A, the detection connection point 68A between the resistor 66 and the resistor 67 is connected to the anode of the diode 64, and the cathode of the diode 64 is connected to the FET 41A in the connection wiring 47A. Is also connected to the detection node 69A on the heater lead wire 23A side.
The diode 64 is provided to prevent a reverse current from flowing from the detection node 69A toward the detection connection point 68A when the FETs 41A, 41B, and 41C are in the ON state.
Further, the detection connection point 68 </ b> A is connected to the first input unit 87 of the microcomputer 80. As a result, the microcomputer 80 can detect the potential V1 of the detection connection point 68A.
The resistance value R1 of the resistor 66 and the resistance value R2 of the resistor 67 are sufficiently larger than the resistance value Rh of the heater 21 (R1, R2 >> Rh). In the present embodiment, further, R1 = R2.

  In the individual disconnection detection circuit 61A, when the disconnection detection signal sig21 output from the fourth output unit 84 of the microcomputer 80 is set to the high level, the transistor 62 and the transistor 63 are turned on. Then, a current flows from the detection power supply 55 to the resistor 66 and the resistor 67 through the transistor 63.

Here, a case is considered where the disconnection detection signal sig21 output from the fourth output unit 84 of the microcomputer 80 is set to the high level and the transistor 63 is turned on when the FETs 41A, 41B, and 41C are not energized.
If the heater 21 and the heater lead wire 23A of the glow plug 20 are not disconnected, the resistance value R2 of the resistor 67 is sufficiently larger than the resistance value Rh of the heater 21. Most of the flowing current flows to the heater 21 through the diode 64. Therefore, the detection potential V1 at the detection connection point 68A is a value that is substantially close to the ground potential (non-disconnection voltage Vs).
On the other hand, when the heater 21 or the heater lead wire 23 </ b> A of the glow plug 20 is disconnected, the current flowing through the transistor 63 flows through the resistor 67 without flowing through the diode 64. Therefore, the detection potential V1 at the detection connection point 68A is a value obtained by dividing the reference potential Vcc by the resistance values R1 and R2, which is Vcc / 2 (= about 2.5 V: disconnection voltage Vt) in this embodiment. Become.
As described above, since the detection potential V1 of the detection connection point 68A varies greatly depending on whether the heater 21 and the heater lead wire 23A of the glow plug 20 are disconnected or not, the detection is made through the first input section 87 of the microcomputer 80. By monitoring the detection potential V1 at the connection point 68A, the disconnection of the heater 21 or the heater lead wire 23A of the glow plug 20 can be detected. The analog voltage input to the first input unit 87 is converted into a digital value using an A / D converter, and the presence or absence of disconnection is determined using this digital value.

Similarly, in the FET 41B, when the FET 41A, 41B, 41C is not energized, the disconnection detection signal sig22 output from the fifth output unit 85 of the microcomputer 80 is set to the high level, the transistor 63 is turned on, The disconnection of the heater 21 or the heater lead wire 23B of the glow plug 20 can be detected by monitoring the detection potential V2 at the detection connection point 68B through the second input unit 88 of the computer 80 (see FIG. 3).
Similarly, in the FET 41C, the disconnection detection signal sig23 output from the sixth output unit 86 of the microcomputer 80 is set to the high level when the energization by the FETs 41A, 41B, and 41C is not performed, and the transistor 63 is turned on. The disconnection of the heater 21 or the heater lead wire 23B of the glow plug 20 can be detected by monitoring the detection potential V3 at the detection connection point 68C through the third input unit 89 of the microcomputer 80 (see FIG. 4).

  Whether the heater 21 of the glow plug 20 is disconnected or whether one of the heater lead wires 23A, 23B, 23C is disconnected is determined by comprehensively determining the three detection potentials V1, V2, V3. Can do. That is, when all of the three detection potentials V1, V2, and V3 become the disconnection voltage Vt (≈Vcc / 2) and indicate a disconnection, the three heater lead wires 23A, 23B, and 23C are disconnected simultaneously. Therefore, it is determined that the heater 21 of the glow plug 20 is disconnected. On the other hand, when any of the three detection potentials V1, V2, and V3 indicates the non-disconnection voltage Vs (a value close to the ground potential), the heater 21 is not disconnected, and the heater lead wires 23A and 23B. , 23C, it can be determined that the one corresponding to the detection connection point 68A or the like having the voltage Vt at the time of disconnection is disconnected.

In the glow plug disconnection detection device 60, disconnection is detected using the individual disconnection detection circuits 61A, 61B, 61C when the battery 50 is not energized to the heater 21 through any of the heater lead wires 23A, 23B, 23C. I do. For example, when heating by the glow plug 20 (heater 21) is not required in the engine, specifically, there is a case where the engine is sufficiently warmed.
Note that even when the heating by the glow plug 20 is performed, such as an after glow period, when the FET 41A is turned on and off to perform duty control (PWM control) (see FIG. 5A), FIG. As shown in (b), the glow energization signal sig11 (sig12, sig13) output from the first output unit 81 (second output unit 82, third output unit 83) of the microcomputer 80 is low level, that is, FET 41A (FET 41B). , FET 41C) during the off-state, the disconnection detection signal sig21 (sig22, sig23) output from the fourth output unit 84 (the fifth output unit 85, the sixth output unit 86) of the microcomputer 80 is set to the high level to detect the disconnection. I do.

Next, in the glow plug disconnection detection apparatus 60, a processing procedure for detecting the presence or absence of disconnection of the heater 21 and the heater lead wires 23A, 23B, and 23C of the glow plug 20 by the microcomputer 80 will be described with reference to FIG.
First, in step S1, information regarding the presence or absence of disconnection is reset and various other initial settings are performed. Here, the detection counter N is set to N = 1.

  Next, in step S2, it is determined whether it is a disconnection detection timing. As this timing, for example, an appropriate timing may be set in advance, for example, every predetermined time from the start of the engine, a period in which the engine is warmed and not heated by the glow plug 20, or immediately after the engine is turned off. it can. In addition, the ECU 90 transmits a signal for permitting detection of disconnection in consideration of the state of the engine, and detects disconnection based on the permission signal, that is, detects the disconnection during the period in which the permission signal is input. It is also possible to set the timing.

Further, in step S3, it is determined whether or not the detection counter N is greater than 3 (N> 3). In the present embodiment, this detection counter N is used to specify which of the heater lead wires 23A, 23B, and 23C is the measurement target. Specifically, when N = 1, the heater lead wire 23A is the inspection target. Similarly, when N = 2, the heater lead wire 23B is subject to inspection, and when N = 3, the heater lead wire 23C is subject to inspection.
As described later, in step S12, the detection counter N is incremented. Therefore, if it is determined Yes (N> 3) in this step S3, that is, if the disconnection detection is completed for any of the three heater lead wires 23A, 23B, and 23C, the disconnection detection is performed again. To prepare, the process returns to step S1.

On the other hand, if No (N ≦ 3), the process proceeds to step S4, where the glow energization signals sig11, sig12, sig13 are all at low level, that is, all of the FETs 41A, 41B, 41 are off, and the heater 21 Confirm that the battery 50 is not energized.
Here, in the case of Yes (non-energization), the process proceeds to step S5. In the case of No (energized), step S4 is repeated, and the process waits until it becomes Yes (non-energized) before proceeding to step S5.

In step S5, the Nth disconnection detection signal sig2N (sig21, sig22, sig23) is set to the high level. As a result, among the individual disconnection detection circuits 61A, 61B, 61C, a circuit corresponding to the Nth disconnection detection signal sig2N is activated, and the detection potential VN at the detection connection point 68A or the like is applied to the heater 21 or the heater lead wire 23A. It becomes a different value (Vt or Vs) depending on the presence or absence of disconnection such as.
Therefore, in step S6, the detected potential VN (V1, V2, V3) is read through the first input unit 87 of the microcomputer 80 or the like.

Further, in step S7, it is checked whether or not the detection potential VN is equal to or higher than a threshold voltage Vth (1.5 V in this example) (VN ≧ Vth).
Here, in the case of No (VN <Vth), it is determined that there is no disconnection in the heater lead wire corresponding to the detection counter N, and in step S8, the ECU 90 is directed to the Nth heater lead wire. A signal indicating that there is no disconnection is transmitted, and the process proceeds to step S12.

On the other hand, if Yes (VN ≧ Vth), it is determined that the heater lead corresponding to the detection counter N is disconnected, and the Nth heater lead is disconnected toward the ECU 90 in step S9. Is transmitted, and the process proceeds to step S12.
Next, in step S10, it is determined whether or not all of the three heater lead wires 23A, 23B, and 23C are disconnected. If it is determined that any of the three heater lead wires 23A, 23B, and 23C is disconnected, it is highly possible that the heater 21 itself is disconnected, not the heater lead wire 23A or the like. is there.
Here, No, that is, when the disconnection detection has not been completed for the three heater lead wires 23A and the like, and the disconnection detection has been completed for the three heater lead wires 23A and the like. If it is determined that the line is not disconnected, the process proceeds to step 12.
On the other hand, if YES in step S10, that is, if any of the three heater lead wires 23A, 23B, and 23C is determined to be disconnected, the process proceeds to step S11, and the heater 21 itself is disconnected toward the ECU 90. A signal to the effect is transmitted, and then the process proceeds to step S12.

  In step S12, the detection counter N is incremented, and the process returns to step S3. In step S3, as described above, it is determined whether disconnection detection is performed for the next heater lead (Yes) or disconnection detection is completed for the three heater lead wires 23A and the like, and thus the process returns to step 1 (No). Is done.

  Thus, according to this processing procedure, disconnection detection can be performed for each heater lead wire 23A and the like and the heater 21 at a predetermined disconnection detection timing, and the result can be transmitted to the ECU 90.

  The ECU 90 can perform appropriate processing according to the transmitted result. For example, when disconnection is detected in the heater 21 or each heater lead wire 23A, a warning that maintenance is required can be issued to the driver.

  In the processing procedure described above, in step 11, a signal indicating that the heater 21 is disconnected is transmitted to the ECU 90. However, when this step S11 is executed, as a precondition thereof, a signal indicating that each of the three heater lead wires 23A, 23B, and 23C has been disconnected by already executing step S9 three times is sent to the ECU 90. Has been sent to. Therefore, it can be considered that the signal indicating that the heater 21 itself is disconnected is also transmitted to the ECU 90 when the three signals are prepared. In this case, steps S10 and S11 may be omitted.

  As described above, the GCU 2 according to the present embodiment includes the glow plug disconnection detection device 60 having the disconnection detection circuit 61. For this reason, in addition to the disconnection in the heater 21 of the glow plug 20, the disconnection of each of the heater lead wires 23 </ b> A, 23 </ b> B, and 23 </ b> C that energizes the heater 21 can be detected appropriately.

  Moreover, in the glow plug disconnection detection device 60, the disconnection detection circuit 61 includes the individual disconnection detection circuit 61A, the individual disconnection detection circuit 61B, and the individual disconnection detection circuit 61C that correspond one-to-one with the heater leads 23A, 23B, and 23C. have. For this reason, the detection results of the individual disconnection detection circuits 61A, 61B, 61C are collected from the microcomputer 80 and transferred to the ECU 90, which is different from the case where one individual disconnection detection means is used by switching. It is possible to easily grasp whether the heater lead wire is broken.

  Further, in the glow plug disconnection detection device 60 provided in the GCU 2 according to the present embodiment, the individual disconnection detection circuits 61A, 61B, and 61C are used during the period when the heater 50 of the glow plug 20 is not energized from the battery 50. The presence or absence of disconnection in the heater lead wires 23A, 23B, 23C or the heater 21 to be inspected is detected. For this reason, it is possible to increase the degree of freedom of the time when the disconnection can be detected as compared with the configuration in which the disconnection is detected while the heater 21 is energized.

Further, the GCU 2 according to the present embodiment has a configuration including a glow plug disconnection detection device 60 and a glow plug energization control device 40.
As a result, in addition to energizing the heater 21, the heater 21 or the heater lead wires 23 </ b> A, 23 </ b> A are connected to the glow plug 20 that is energized through the three heater lead wires 23 </ b> A, 23 </ b> B, 23 </ b> C connected in parallel to the heater 21. It is possible to appropriately detect the disconnection of 23B and 23C.

  In the GCU 2 according to this embodiment, as can be easily understood from FIG. 1, the glow plug energization control device 40 and the glow plug disconnection detection device 60 share the microcomputer 80. Thereby, GCU2 can be comprised at low cost. In the present embodiment, the GCU 2 is configured by integrating the glow plug energization control device 40 and the glow plug disconnection detection device 60. However, the glow plug energization control device 40 and the glow plug disconnection detection device 60 are configured separately. You may do it. In this case, each can be configured to have a separate microcomputer.

(Modification 1)
Next, a modification of the above-described embodiment will be described with reference to FIG.
In the glow plug energization system 1 with a disconnection detection function shown in the above-described embodiment, in addition to the heater 21, three heater lead wires 23 </ b> A, 23 </ b> B, and 23 </ b> C electrically connected in parallel to one end 21 </ b> N of the heater 21 are provided. For the glow plug 20, an example in which disconnection detection of the heater 21, each heater lead wire 23 </ b> A, and the like was performed using the GCU 2 was shown.
On the other hand, the glow plug energization system 101 with the disconnection detection function of the first modification uses the same GCU2 as in the embodiment, but in parallel with the glow plug 120 having the heater 121 and the energization terminal 122 of the glow plug 120. The difference is that the three heater lead wires 123A, 123B, and 123C to be connected are to be inspected.

  Thus, even when the glow plug 120 is energized via a plurality of (three) heater lead wires 123A, etc., according to GCU2 (glow plug disconnection detection device 60), the same as in the above-described embodiment. Thus, the disconnection detection of the three heater lead wires 123A, 123B, 123C and the disconnection detection of the heater 121 can be performed.

(Modification 2)
A second modification of the embodiment will be described with reference to FIGS. 6 and 8.
In the GCU 2 according to the above-described embodiment, the glow plug disconnection detection device 60 includes the disconnection detection circuit 61 having the individual disconnection detection circuits 61A, 61B, and 61C corresponding to the heater lead wires 23A, 23B, and 23C on a one-to-one basis. Thus, the disconnection of each heater lead wire 23A, 23B, 23C can be detected.

On the other hand, in the second modification, the glow plug disconnection detection device 260 of the GCU 202 is replaced with a single disconnection detection circuit 261 (individual disconnection detection circuit 265) by using a lead wire changeover switch 270, and any heater. The lead wires 23A, 23B, and 23C are configured to be connectable.
However, the method of detecting the presence or absence of disconnection of each heater lead wire 23A, 23B, 23C and the heater 21, the configuration of the glow plug energization control device 240, and the microcomputer 280 of the glow plug disconnection detection device 260 are connected to the ECU 90. This is the same as the embodiment.
Therefore, parts different from the embodiment will be mainly described, and the same parts are denoted by the same reference numerals as those in the embodiment, and the description will be omitted or simplified.

  The GCU 202 according to the second modification includes a glow plug energization control device 240 and a glow plug disconnection detection device 260. The GCU 202 includes a microcomputer 280 and, together with the glow plug 20, forms a glow plug energization system GCU 201 with a disconnection detection function. In the glow plug energization system GCU201 with disconnection detection function, the glow plug energization control device 240 and the glow plug 20 constitute a glow plug energization system 210 described below.

First, the glow plug energization system 210 will be described.
The glow plug energization system 210 includes the glow plug 20 and the glow plug energization control device 240 as described above.
Among these, the glow plug energization control device 240 includes, in addition to the microcomputer 280, FETs 41A, 41B, 41C and switch circuits 42A, 42B, 42C having the same circuit configuration as the glow plug energization control device 40 of the embodiment.
Note that the microcomputer 280 includes a first output unit 81, a second output unit 82, and a third output unit 83 that output glow energization signals sig11, sig12, and sig13, similarly to the microcomputer 80 of the embodiment. In addition, it includes a fourth output unit 284 that outputs a disconnection detection signal sig2, and a switching instruction unit 286 that outputs a lead wire switching signal sig3.

Next, the disconnection detection device 260 will be described.
The disconnection detection device 260 detects the presence or absence of disconnection in the heater 21 of the glow plug 20 as well as the disconnection detection device 60 of the embodiment, and three heater lead wires 23A, 23B, and 23C that conduct to the heater 21. Is provided with a disconnection detection circuit 261 for detecting the presence or absence of each disconnection. The disconnection detection circuit 261 includes an individual disconnection detection circuit 265 and a changeover switch 270.
Among these, the individual disconnection detection circuit 265 includes transistors 62 and 63, a diode 64, and resistors 65, 66, and 67, and has the same circuit configuration as the individual disconnection detection circuit 61A and the like in the embodiment.

On the other hand, the change-over switch 270 (switching means) is a switch for selecting a heater lead wire that is detected by the individual breakage detection circuit 265 among the three heater lead wires 23A, 23B, and 23C. The changeover switch 270 has three connection terminals 271A, 271B, and 271C for switching the connection with the connection terminal 272.
Among these, the connection terminal 271A is connected to the heater lead wire 23A at the detection node 269A on the heater lead wire 23A side of the FET 41A in the connection wiring 47A. Similarly, the connection terminal 271B is connected to the heater lead wire 23B at the detection node 269B on the heater lead wire 23B side of the FET 41B in the connection wiring 47B. Further, the connection terminal 271C is connected to the heater lead wire 23C at the detection node 269C on the heater lead wire 23C side of the FET 41C in the connection wiring 47C.
The connection terminal 272 of the changeover switch 270 is connected to the cathode side of the diode 64.
Further, the changeover switch 270 is connected to the changeover instruction unit 286 of the microcomputer 280. The changeover switch 270 is configured so that the connection between the connection terminal 272 and the connection terminals 271A, 271B, and 271C can be changed by the lead wire switching signal sig3 output from the changeover instruction unit 286.

Next, in the glow plug disconnection detection device 260, a processing procedure for detecting the presence or absence of disconnection of the heater 21 and the heater lead wires 23A, 23B, and 23C of the glow plug 20 by the microcomputer 280 will be described with reference to FIG. .
Note that the processing procedure in the second modification differs from the processing procedure in the above-described embodiment only in that step S205 indicated by a broken line in FIG. 6 is executed instead of step S5, and the other steps are the same. Therefore, only step S205 will be described.

  In step S205, the switching instruction unit 286 of the microcomputer 280 outputs the lead wire switching signal sig3. Then, the changeover switch 270 selects and switches the connection terminal that is electrically connected to the connection terminal 272 from the three connection terminals 271A, 271B, and 271C. Specifically, the connection terminal connected to the heater lead wire corresponding to the value of the detection counter N is selected. Thereby, the heater lead wire (heater lead wire to be inspected) connected to the individual disconnection detection circuit 265 is switched. Further, sig2 output from the fourth output unit 284 of the microcomputer 280 is set to the high level. As a result, the detection potential VN at the detection connection point 268 differs depending on whether or not the glow plug heater 21 and the heater lead wire to be inspected are disconnected. Thereafter, processing is performed in the same manner as in the embodiment, and disconnection detection can be performed for the three heater lead wires by sequentially switching the connection of the changeover switch 270.

As described above, the glow plug disconnection detection device 260 according to this modification includes the changeover switch 270 in addition to the individual disconnection detection circuit 265.
For this reason, the number of the individual disconnection detection circuits 265 is reduced from the number of individual disconnection detection means (three in this example) required when corresponding to each heater lead wire 23A, 23B, 23C on a one-to-one basis. I was able to. Thereby, the glow plug disconnection detection device 260 can be further reduced in size and cost.

  In the above, the present invention has been described with reference to the embodiment and the first and second modifications. However, the present invention is not limited to the above-described embodiment and the first and second modifications, and is within a scope not departing from the gist thereof. Needless to say, the present invention can be appropriately changed and applied.

It is a circuit diagram of the glow plug energization system with a disconnection detection function concerning an embodiment. It is explanatory drawing of the individual disconnection detection circuit 61A in the glow plug energization system with a disconnection detection function which concerns on embodiment. It is explanatory drawing of the individual disconnection detection circuit 61B in the glow plug electricity supply system with a disconnection detection function which concerns on embodiment. It is explanatory drawing of the individual disconnection detection circuit 61C in the glow plug electricity supply system with a disconnection detection function which concerns on embodiment. It is a timing chart about a glow energization signal and a disconnection detection signal in case energization of a glow plug is performed by PWM control, (a) shows a disconnection detection signal and (b) shows a glow energization signal and a disconnection detection signal. It is the flowchart explaining the method of detecting the presence or absence of disconnection of each heater lead wire and a heater with a glow plug disconnection detection apparatus. It is a circuit diagram of a glow plug energization system with a disconnection detection function according to Modification 1. It is a circuit diagram of the glow plug energization system with a disconnection detection function concerning modification 2.

Explanation of symbols

2,202 GCU (Glow plug energization control device with disconnection detection function)
10, 110, 210 Glow plug energization system 20, 120 Glow plug 21, 121 Heater 21N, 121N One end of heater 122 Energization terminal 23A, 23B, 23C, 123A, 123B, 123C Heater lead wire 40, 240 Glow plug energization control device 41A , 41B, 41C FET (energization switch means)
50 batteries (power)
60,260 Glow plug disconnection detection device 61,261 Disconnection detection circuit (disconnection detection means)
61A, 61B, 61C, 265 Individual disconnection detection circuit (individual disconnection detection means)
270 Lead wire changeover switch (switching means)
Vs Voltage when not disconnected Vt Voltage when disconnected

Claims (6)

A glow plug having a heater that generates heat when energized and a plurality of heater lead wires electrically connected in parallel to one end of the heater, or a heater that generates heat when energized and an energization terminal electrically connected to one end of the heater A plurality of heater lead wires electrically connected in parallel to the glow plug and the energizing terminal;
A glow plug energization system comprising: a glow plug energization control device including a plurality of energization switch means for intermittently supplying a current flowing through the plurality of heater lead wires from a power source to the heater of the glow plug for each heater lead wire of,
A glow plug disconnection detection device for detecting the presence or absence of disconnection of the heater,
A glow plug disconnection detecting device comprising disconnection detecting means for detecting the presence or absence of disconnection of each of the heater lead wires. The glow plug disconnection detection device according to claim 1,
The disconnection detecting means is
A glow plug disconnection detecting device having a plurality of individual disconnection detecting means for detecting the presence or absence of disconnection of the heater lead corresponding to each heater lead. The glow plug disconnection detection device according to claim 1,
The disconnection detecting means is
Individual disconnection detecting means for detecting the presence or absence of disconnection of the heater lead wire, which is a single or fewer than the number of heater lead wires,
A glow plug disconnection detection device comprising: switching means for switching connection with the heater lead wire detected by the individual disconnection detection means. A glow plug disconnection detecting device according to claim 2 or claim 3,
The individual disconnection detecting means is
A glow plug disconnection detection device that detects the presence or absence of disconnection in the heater lead wire to be inspected or in the heater when the heater of the glow plug is not energized through any of the energization switch means from the power source. The glow plug disconnection detection device according to claim 4,
The individual disconnection detecting means is
When energizing the heater of the glow plug from the power source through any of the energization switch means, energizing the heater lead wire and the heater to be inspected,
When the heater lead wire to be inspected or the heater is disconnected, the disconnection voltage generated in the heater lead wire, and
Whether the inspection subject heater lead wire or the heater is disconnected, depending on which of the non-disconnection voltage that occurs in the heater lead wire when the inspection subject heater lead wire and the heater are conductive. Glow plug disconnection detector. The glow plug disconnection detection device according to any one of claims 1 to 5,
A glow plug energization control device with a disconnection detection function comprising the glow plug energization control device.

Images