JP3129030U - Ignition device - Google Patents

Abstract

An ignition device capable of accurately determining whether or not an ignition operation of an ignition device is normal by measuring a discharge current flowing in a discharge circuit, and capable of maintaining extremely high safety of a combustion device. To do.
In an ignition device having a discharge circuit in which a discharge capacitor, a discharge switch, and a spark plug for spark discharge are connected in series, the discharge circuit is connected to the discharge circuit when the spark plug is discharged. A detection sensor 10 that detects a change per unit time when the flowing discharge current falls, a determination circuit 11 that determines whether spark discharge is normal or abnormal based on the discharge current, and an output that outputs a determination result of the determination circuit 11 A switching circuit 12 is provided.
[Selection] Figure 1

Description

  The present invention relates to an ignition device, and more particularly to an ignition device capable of confirming normality and abnormality of spark discharge of an ignition plug.

  In general, an ignition device for fuel ignition is used in a power generation burner or a marine burner.

  The conventional ignition device is formed so as to cause a discharge current to flow through the spark plug and generate a spark discharge in the spark plug to ignite the burner.

  The conventional ignition device is configured to supply the electric charge stored in the discharge capacitor to the spark plug by turning on the switch to generate the spark discharge in the spark plug, so that the spark discharge is normally performed. It was difficult to determine whether or not it occurred, and it was determined visually.

  When the spark discharge does not occur normally, it is predicted that the fuel in the combustion device leaks wastefully or leads to an accident. Therefore, when the combustion apparatus is moved, it is necessary to confirm that a shortage such as fuel leakage does not occur by a preliminary inspection.

  In view of this, there has been proposed a device that detects whether or not the ignition operation of the ignition device is normal by measuring a peak voltage at the start of spark discharge between the electrodes of the spark plug (see Patent Document 1).

JP-A-10-306765

  However, in the conventional apparatus, it is impossible to properly determine whether or not the ignition operation is normal. This is because even if the peak voltage at the start of spark discharge between the electrodes of the spark plug is large enough to generate spark discharge, spark discharge may not be properly generated between the electrodes of the spark plug. Therefore, it cannot be properly determined based on the magnitude of the peak voltage.

  The present invention has been made in view of these points, and it is possible to accurately determine whether or not the ignition operation of the ignition device is normal by measuring the discharge current flowing through the discharge circuit. It is an object of the present invention to provide an ignition device that can keep the temperature extremely high.

  In order to achieve the above object, an ignition device according to the present invention is an ignition device having a discharge circuit in which a discharge capacitor, a discharge switch, and a spark plug for spark discharge are connected in series. A detection sensor for detecting a change per unit time when the discharge current flowing through the discharge circuit falls, a determination circuit for determining whether the spark discharge is normal or abnormal based on the discharge current, and a determination result of the determination circuit is output. An output switching circuit is provided.

  According to the ignition device of the present invention, it is detected that the change per unit time at the fall of the discharge current flowing in the discharge circuit during discharge of the spark plug is different between when the spark discharge is normal and when it is abnormal. By doing so, it is possible to reliably detect, judge and output the normality and abnormality of the spark discharge by the spark plug, thereby improving the safety and reliability of the spark plug and making it easy to use. .

  In the ignition device of the present invention, the detection sensor may be formed so as to detect a differential value with respect to time of the discharge current. As a result, it is possible to accurately detect a change per unit time when the discharge current flowing through the discharge circuit falls.

  Further, in the ignition device of the present invention, the determination circuit determines that the spark discharge is normal when the differential value obtained from the detection sensor is obtained after the normal discharge time has elapsed from the start of discharge, It is determined that the spark discharge is abnormal when a normal discharge time elapses from the start of discharge and is obtained after a short time has elapsed thereafter, and when the differential value cannot be obtained from the detection sensor, the spark discharge is abnormal. It is good to form so that it may be judged. As a result, it is possible to accurately determine whether the spark discharge is normal or abnormal using the differential value.

  In the ignition device of the present invention, the output switching circuit outputs that the spark discharge is normal when the output of the determination circuit determines that the spark discharge is normal, and the output of the determination circuit is It may be formed so as to output that the spark discharge is abnormal when it is determined that the spark discharge is abnormal. As a result, it is possible to reliably output the normal and abnormal spark discharge determined accurately by the output switching circuit.

  As described above, according to the ignition device according to the present invention, it is possible to accurately determine whether or not the ignition operation of the ignition device is normal by measuring the discharge current flowing through the discharge circuit, and thus the safety of the combustion device. As a result, it is possible to exhibit excellent effects such as being able to maintain extremely high properties.

  More specifically, in the ignition device of the present invention, the change per unit time at the fall of the discharge current flowing in the discharge circuit during discharge of the spark plug is different between when the spark discharge is normal and when it is abnormal. By detecting this, it is possible to reliably detect, judge and output the normality and abnormality of the spark discharge caused by the spark plug, thereby improving the safety and reliability of the spark plug and making it easy to use. It will be.

  In addition, the ignition device of the present invention accurately detects changes per unit time at the fall of the discharge current flowing in the discharge circuit by forming a detection sensor to detect a differential value of the discharge current with time. can do.

  In the ignition device of the present invention, the determination circuit determines that the spark discharge is normal when the differential value obtained from the detection sensor is obtained after a normal discharge time has elapsed from the start of discharge. It is determined that the spark discharge is abnormal when the normal discharge time elapses from the start and is obtained after the short time has elapsed thereafter, and when the differential value cannot be obtained from the detection sensor, the spark discharge is abnormal. By forming so as to determine that there is, it is possible to accurately determine whether the spark discharge is normal or abnormal using the differential value.

  In the ignition device of the present invention, the output switching circuit outputs that the spark discharge is normal when the output of the determination circuit determines that the spark discharge is normal, and the output of the determination circuit is the When it is determined that the spark discharge is abnormal, it is configured to output that the spark discharge is abnormal, so that the output switching circuit can reliably output the normal or abnormal spark discharge that is accurately determined. Can do.

  Hereinafter, an embodiment of an ignition device according to the present invention will be described with reference to FIGS.

  1 to 3 show an embodiment of the ignition device of the present invention.

  FIG. 1 shows a circuit diagram of the ignition device of the present invention. The ignition device 1 according to this embodiment includes a charging circuit 2 and a discharging circuit 3.

  The charging circuit 2 is formed by connecting a DC power source 4 as a power source, a charging resistor 5 and a discharge capacitor 6 in series. The discharge capacitor 6 is charged to an arbitrary voltage from the DC power supply 4 via the charging resistor 5. Further, the charging circuit 2 may be provided with a switch for selecting charging start / stop.

  The discharge circuit 3 is formed by connecting a discharge capacitor 6, a discharge switch 7 composed of a thyristor, and a spark plug 8 in series. A protective diode 9 is connected to the discharge capacitor 6 in parallel.

  In the present embodiment, a detection sensor 10 that detects a discharge current i flowing through the discharge circuit 3 is provided between the spark plug 8 and the discharge capacitor 6. The discharge current i has properties as shown in FIG. That is, when the gap of the spark plug 8 is normal, the spark discharge of the spark plug 8 is normally performed, and the discharge current i flowing through the discharge circuit 3 is as shown by the solid line in FIG. Changes over time. When an abnormality occurs such as when there is no gap in the spark plug 8, a discharge (no spark) occurs, but a short circuit occurs and the discharge current i flowing through the discharge circuit 3 is as shown by the broken line in FIG. Change over time. When the discharge circuit 3 is open due to some abnormality, the discharge current i does not flow through the discharge circuit 3. Corresponding to the nature of the discharge current i, the detection sensor 10 in the present embodiment is formed to detect a change per unit time when the discharge current i flowing through the discharge circuit 3 falls. Specifically, it is configured to detect the differential value of the discharge current i with time. The differential value of the discharge current i shown in FIG. 2A is as shown in FIG. That is, since the discharge current i rises sharply at t0 at the start of discharge, the discharge start output S as a positive differential value output of the discharge current i is obtained. When the spark discharge is normally performed, the discharge current i rising at the start of discharge t0 starts to gradually fall as indicated by the solid line in FIG. 2A, and when the normal discharge time t1 has elapsed from the start of discharge. Since the amount of fall changes so as to decrease rapidly, an output A during normal discharge is obtained as a negative differential value output having a large discharge current i, as shown in FIG. When a spark discharge has occurred but is abnormal, the discharge current i rising at the start of discharge t0 starts to gradually fall as indicated by the broken line in FIG. 2A, and the amount of fall when the normal discharge time t1 has elapsed. Since the rate of change in voltage is constant, no differential value is output, and when the short time t2, which is an abnormal discharge time, has elapsed since the start of discharge, the amount of fall changes so as to decrease rapidly. ), An abnormal discharge output B is obtained as a negative differential value output with a small discharge current i. Accordingly, the detection sensor 10 outputs a discharge start output S, a normal discharge output A, and an abnormal discharge output B shown in FIG. 2B as differential value outputs.

  The output of the detection sensor 10 is formed so as to be input to a determination circuit 11 for determining whether the spark discharge is normal or abnormal by the discharge current i. In the present embodiment, the determination circuit 11 determines that the spark discharge is normal when the differential value input from the detection sensor 10 is obtained as the normal discharge output A after the normal discharge time t1 has elapsed from the discharge start time t0. If the normal discharge time t1 has elapsed from the start of discharge t0 and the abnormal discharge output B is obtained after the short time t2 has elapsed, it is determined that the spark discharge is abnormal. When the differential value cannot be obtained, the spark discharge is determined to be abnormal.

  The output of the determination circuit 11 is input to the output switching circuit 12 that outputs the determination result. In the present embodiment, the output switching circuit 12 outputs that the spark discharge is normal when the output of the determination circuit 11 determines that the spark discharge is normal, and the output of the determination circuit 11 indicates that the spark discharge is abnormal. When it is determined that the spark discharge is abnormal, the fact that the spark discharge is abnormal is output. As the output format of the output switching circuit 12, a blue lamp is lit when the spark discharge is normal, a red lamp is lit when short or open is abnormal, and the liquid crystal display is normal or short. It is good to display the word “open”, to output normal, short, open by sound by a sound generator, or to output a combination of these methods (the output means are not shown).

  Moreover, in this embodiment, it forms so that the detection sensor 10, the determination circuit 11, and the output switching circuit 12 may be relatedly operated by the controller 13 which mounts CPU.

  Next, the operation of this embodiment will be described.

  The discharge capacitor 6 of the charging circuit 2 of the ignition device 1 is charged with a voltage sufficient for ignition of the spark plug 8 from the DC power source 4 through the charging resistor 5 and is brought into a standby state.

  In this standby state, as shown in step ST1 of FIG. 3, when the discharge switch 7 is turned on, the electricity stored by the discharge capacitor 6 is supplied to the spark plug 8, the spark plug 8 is ignited, and a spark discharge is generated. The discharge current i flows through the discharge circuit 3. At the same time, the controller 13 causes the detection sensor 10, the determination circuit 11, and the output switching circuit 12 to perform related operations.

  Subsequently, it is monitored that the normal discharge time t1 elapses from the discharge start time t0 (step ST2). When the normal discharge time t1 elapses, it is determined whether or not the normal discharge output A is detected from the detection sensor 10. 11 (step ST3).

  If it is determined in step ST3 that the output A during normal discharge has been detected, the process proceeds to step ST4, where the output switching circuit 12 outputs that a normal spark discharge has been performed by the spark plug 8, and a series of steps. This process ends, and the burner is ignited by a normal spark discharge.

  When the normal discharge output A is not detected in step ST3, the process proceeds to step ST5 to monitor that the short time t2 has elapsed from the discharge start time t0. When the short time t2 has elapsed, the detection sensor 10 detects abnormal discharge. Whether or not the hour output B is detected is determined by the determination circuit 11 (step ST6).

  If it is determined in step ST6 that the abnormal discharge output B has been detected, the process proceeds to step ST7, where the output switching circuit 12 is discharged by the spark plug 8 (no spark) but shorted. Thus, a series of processes is completed, and the supply of fuel to the burner is stopped.

  If the abnormal discharge output B is not detected in step ST6, the process proceeds to step ST8, where it is determined that the discharge circuit 3 is open, and the output switching circuit 12 outputs that the discharge circuit 3 is open. Thus, a series of processes is completed, and the supply of fuel to the burner is stopped.

  Thus, according to the ignition device 1 of the present embodiment, it is possible to accurately determine whether or not the ignition operation of the ignition device 1 is normal by measuring the discharge current i flowing through the discharge circuit 3.

  In addition, this invention is not limited to the said embodiment, A various change is possible as needed.

The circuit diagram which shows the circuit structure of one Embodiment of the ignition device of this invention (A) is a characteristic diagram showing a temporal change degree of the discharge current, (b) is a diagram showing an output based on a differential value of the discharge current of (a). Flow chart showing the operation of the ignition device of the present invention

Explanation of symbols

6 Discharge capacitor 7 Discharge switch 8 Spark plug 10 Detection sensor 11 Judgment circuit 12 Output switching circuit

Claims (4)

  In an ignition device having a discharge circuit in which a discharge capacitor, a discharge switch, and a spark plug for spark discharge are connected in series, per unit time when the discharge current flowing through the discharge circuit falls during discharge of the spark plug An ignition device, comprising: a detection sensor that detects a change in the discharge current; a determination circuit that determines whether spark discharge is normal or abnormal based on the discharge current; and an output switching circuit that outputs a determination result of the determination circuit.   The ignition device according to claim 1, wherein the detection sensor detects a differential value of the discharge current with time.   The determination circuit determines that the spark discharge is normal when the differential value obtained from the detection sensor is obtained after the normal discharge time has elapsed from the start of discharge, and the normal discharge time has elapsed from the start of discharge. It is determined that the spark discharge is abnormal when it is obtained after a short time has elapsed thereafter, and the spark discharge is determined to be abnormal when the differential value is not obtained from the detection sensor. The ignition device according to claim 2.   The output switching circuit outputs that the spark discharge is normal when the output of the determination circuit determines that the spark discharge is normal, and the output of the determination circuit determines that the spark discharge is abnormal The ignition device according to claim 3, wherein the ignition device outputs that the spark discharge is abnormal.

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