JP2014173487A - Ignition device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ignition device capable of effectively suppressing electrode wear of an ignition plug while securing ignitability.SOLUTION: An ignition device has an ignition coil; an ignition plug; and voltage limiting means for limiting an absolute value of voltage applied between electrodes of the ignition plug by electric energy supplied from the ignition coil, so that it is not over a prescribed voltage limit value. The voltage limit value is different between a first stage S1 by termination of a discharge voltage portion generating on the ignition plug first by electric energy supplied to the ignition plug, and a second stage S2 thereafter. The voltage limit value Vh2 of the second stage S2 is lower than the voltage limit value Vh1 of the first stage S1.

Description

  In the present invention, an ignition coil having a primary coil and a secondary coil magnetically coupled to the primary coil, and a high voltage is applied between the center electrode and the ground electrode based on the magnetic energy stored in the ignition coil. It is related with an ignition device provided with the ignition plug which produces a discharge spark between these electrodes by this.

  In recent years, the compression ratio of a gasoline engine tends to be increased by adopting a supercharger or the like in order to improve fuel efficiency or reduce costs by downsizing. When the compression ratio is increased, the in-cylinder pressure at the time when the spark is generated in the spark plug increases, and the discharge voltage of the spark plug increases. As the discharge voltage increases, when the spark plug electrode wears out due to an increase in travel distance, etc., the discharge voltage exceeds the dielectric breakdown limit voltage of the plug insulator at an early stage, and the reliability of the spark plug decreases. There is a risk. At this time, a discharge spark cannot be generated, and the engine may be misfired.

  In order to cope with such a problem, the present inventors have focused on a technique for limiting the discharge voltage of the spark plug with a predetermined voltage by using a constant voltage element such as a Zener diode or a varistor as shown in Patent Document 1 below. . This technology will be described in detail. At one end of the secondary side ends of the ignition coil, a center electrode of the spark plug, and a constant voltage element that allows current to flow when the voltage between the terminals is equal to or higher than the predetermined voltage, Is connected. Of the two ends of the constant voltage element, the opposite side to the center electrode side is grounded.

  According to such a configuration, when the applied voltage between the electrodes of the spark plug attempts to exceed a predetermined voltage, the applied voltage is limited to the predetermined voltage and is flattened. Then, the gas state in the gap is brought into a state suitable for discharge within a period in which the applied voltage is maintained at a predetermined voltage, so that a discharge spark is generated between the electrodes. Thereby, it can avoid that the discharge voltage of a spark plug becomes high too much, and can suppress the fall of the reliability of a spark plug.

Japanese Patent Publication No. 6-80313

  By the way, the present inventors have obtained the knowledge described below when adopting the above technique.

  Although the present inventors can avoid the discharge voltage of the spark plug from becoming excessively high by adopting the above technique, a spark is caused by the flow rate of unburned gas after the start of discharge, and so-called blowout occurs. If the induced power generated in the secondary coil remains when this blow-off occurs, the voltage rises again and re-discharge may occur. The knowledge that the one where the voltage value at the time of discharge becomes low decreases was acquired.

That is, if the gas flow in the vicinity of the spark discharge gap of the spark plug is large, re-discharge occurs after the first discharge, which may cause the electrode to wear out. That is, after the first discharge is generated by the electrical energy supplied from the ignition coil to the spark plug, the induction discharge is generated. The induction discharge is caused to flow by the air flow in the combustion chamber and blown off. However, if the electric energy applied to the spark plug remains, it may be discharged again. It is conceivable that the electrode is consumed by repeating this re-discharge. The voltage of such re-discharge is usually not as high as the voltage of the first discharge, but repeated re-discharge at a certain high voltage is not desirable from the viewpoint of electrode wear resistance, Capacitive discharge generated at the leading portion further accelerates electrode wear and is undesirable.
On the other hand, in order to generate a spark discharge between the electrodes of the spark plug by the electric energy supplied from the ignition coil, the voltage applied between the electrodes needs to be a certain high voltage.

  The present invention has been made in view of such a background, and an object of the present invention is to provide an ignition device capable of effectively suppressing electrode consumption of an ignition plug while ensuring ignitability.

One aspect of the present invention is an ignition coil having a primary coil and a secondary coil magnetically coupled to the primary coil;
A spark plug that generates a discharge spark between these electrodes by applying a voltage between the center electrode and the ground electrode based on the magnetic energy stored in the ignition coil;
Voltage limiting means for limiting the absolute value of the voltage applied between the electrodes of the spark plug by the electrical energy supplied from the ignition coil so as not to exceed a predetermined voltage limit value;
The voltage limiting means sets the voltage limit value to a first stage until a discharge voltage portion first generated in the spark plug by the electrical energy supplied to the spark plug ends, and a second stage thereafter. The ignition device is characterized in that the voltage limit value in the second stage is set lower than the voltage limit value in the first stage (Claim 1).

  The voltage limiting means is configured such that the absolute value of the voltage applied to the spark plug does not exceed a predetermined voltage limiting value. That is, a voltage is applied between the electrodes of the spark plug by the electrical energy supplied from the ignition coil to the spark plug, and this voltage can be made equal to or lower than the voltage limit value. The voltage limit value is different between the first stage and the second stage. Thereby, the discharge voltage of the spark plug can be sufficiently reduced in each of the first stage and the second stage.

The second stage voltage limit value is lower than the first stage voltage limit value. That is, the voltage limit value in the second stage can be lowered while maintaining the voltage limit value in the first stage to a certain level.
As a result, in the first stage, the discharge voltage portion first generated in the spark plug by the electric energy supplied to the spark plug can be generated at a somewhat high voltage. Therefore, a spark discharge can be generated in the spark discharge gap without causing dielectric breakdown in a portion other than the spark discharge gap between the center electrode and the ground electrode. That is, the first discharge can be surely generated, and as a result, misfire of the internal combustion engine can be prevented.
On the other hand, in the second stage, it is possible to reduce the re-discharge voltage that can be repeatedly continued after the first discharge. Thereby, electrode consumption of the spark plug due to repeated re-discharge can be suppressed.

  As described above, according to the present invention, it is possible to provide an ignition device capable of effectively suppressing electrode consumption of an ignition plug while ensuring ignitability.

1 is a circuit configuration diagram of an ignition device in Embodiment 1. FIG. The diagram which shows the operation | movement of the voltage limiting means in Example 1, and the time change of the change of the electric current value which flows into the secondary voltage and the Zener diode near the secondary coil. The circuit block diagram of the ignition device in Example 2. FIG.

The ignition device can be used in, for example, a vehicle internal combustion engine.
For example, a mixed gas of fuel and air is supplied to the combustion chamber of the internal combustion engine in which the ignition plug is mounted. It is preferable that gas flow occurs in the combustion chamber. Examples of the airflow include a tumble flow, a swirl flow, or a combination of these.
The capacitive discharge is, for example, a discharge that is generated when the charge stored in the internal capacitance of the ignition coil is released. In addition to capacitive discharge, spark discharge in the spark plug includes inductive discharge generated by releasing electromagnetic induction energy in the ignition coil.

  The discharge that occurs first means the discharge that occurs first by supplying energy once from the ignition coil to the spark plug. That is, the energy supply from the ignition coil to the spark plug is repeatedly and intermittently performed at a predetermined timing. However, the capacity discharge first generated in the spark discharge gap of the spark plug by each energy supply is generated as described above. Discharge ". In the present specification, this is also appropriately expressed as “first discharge” or the like.

  Further, the first stage voltage limit value and the second stage voltage limit value can be appropriately set according to, for example, the specifications of the internal combustion engine, the specifications of the spark plug, and the like. The voltage limit value in the first stage is set to such an extent that the first discharge can be secured while reducing the discharge voltage, for example. The voltage limit value in the first stage can be set to any value of 20 to 50 kV, for example. In particular, a value around 38 kV is a suitable value from each withstand voltage specification of the ignition plug and the ignition coil component and the ignition voltage characteristic to the engine.

  Further, as the voltage limit value in the second stage, for example, it is possible to sufficiently ensure the ignitability by re-discharge while sufficiently suppressing the electrode consumption of the spark plug due to re-discharge repeated after the first discharge. To the extent. The voltage limit value in the second stage can be set to any value of 1 to 20 kV, for example.

  The voltage limiting means can be configured to switch and set the voltage limit value between two different values (claim 2). In this case, the first-stage voltage limit value and the lower second-stage voltage limit value can be easily set.

  The voltage limiting means is preferably provided on the secondary coil side. In this case, the first stage voltage limit value and the second stage voltage limit value can be set more accurately. In other words, the voltage limiting means can be provided on the primary coil side, but the voltage limiting value can be set more accurately if it is provided on the secondary coil side.

  The voltage limiting means may comprise a switching element and a plurality of constant voltage elements. In this case, the voltage limit value can be easily switched and set accurately. Further, by using the constant voltage element, it is possible to finely set the voltage limit value. As the constant voltage element, for example, a Zener diode, an avalanche diode, a varistor or the like can be used. As the switching element, for example, a MOSFET (MOS type field effect transistor), an IGBT (insulated gate bipolar transistor), or the like can be used.

  The plurality of constant voltage elements are connected in series to each other, the switching element is connected to a connection point of a pair of constant voltage elements connected in series to each other, and the voltage limiting means includes It is preferably connected in parallel with the spark plug (claim 5). In this case, since the pair of constant voltage elements are connected in series with each other, the electric energy emitted from the voltage limiting means can be dispersed and emitted from the plurality of constant voltage elements. That is, the heat generated due to the release of electrical energy can be distributed to a plurality of constant voltage elements. For this reason, heat generation in each part is suppressed, and the heat dissipation means can be easily downsized or eliminated. In addition, since the withstand voltage of each constant voltage element can be reduced, it is easy to reduce the size and cost of the apparatus.

Example 1
An embodiment of the ignition device will be described with reference to FIGS.
As shown in FIG. 1, the ignition device 1 of this example includes an ignition coil 5, a spark plug 2, and a voltage limiting means 3.
The ignition coil 5 has a primary coil 51 and a secondary coil 52 magnetically coupled to the primary coil 51. The spark plug 2 generates a discharge spark between these electrodes when a voltage is applied between the center electrode 21 and the ground electrode 22 based on the magnetic energy stored in the ignition coil 5. The voltage limiting means limits the absolute value of the voltage V2 applied between the electrodes of the spark plug 2 by the electric energy supplied from the ignition coil 5 so as not to exceed a predetermined voltage limit value.

  As shown in FIG. 2, the voltage limit value includes a first stage S1 until the discharge voltage portion initially generated in the spark plug 2 by the electrical energy supplied from the ignition coil 5 is terminated, and a second stage S2 thereafter. And different. The voltage limit value Vh2 in the second stage S2 is lower than the voltage limit value Vh1 in the first stage S1.

  The ignition device 1 has an igniter 6 for energizing and shutting off the primary coil 51. Further, the voltage limiting means 3 is configured so that the voltage limit value can be switched and set between two different values Vh1 and Vh2. The voltage limiting means 3 is provided on the secondary coil 52 side, and includes one switching element 31 and zener diodes 321 and 322 as two constant voltage elements. The two Zener diodes 321 and 322 are connected in series with each other. The switching element 31 is connected to a connection point between a pair of Zener diodes 321 and 322 connected in series with each other. The voltage limiting means 3 is connected in parallel with the spark plug 2.

  The spark plug 2 has a center electrode 21 and a ground electrode 22, and a spark discharge gap G is formed between the center electrode 21 and the ground electrode 22. The ground electrode 22 is grounded. Further, the center electrode 21 is configured to have a low potential with respect to the ground electrode 22. That is, when a voltage is applied between the center electrode 21 and the ground electrode 22 by the ignition coil 5, the potential of the center electrode 21 becomes negative.

  The ignition device 1 of this example can be used for, for example, a vehicle internal combustion engine. For example, a mixed gas of fuel and air is supplied to the combustion chamber. In the combustion chamber, for example, a gas flow such as a tumble flow, a swirl flow, or a combination thereof is generated.

  The power source 4 is a DC power source, and a primary coil 51 of the ignition coil 5 is connected to the positive electrode thereof. A terminal of the primary coil 51 opposite to the side connected to the power source 4 is connected to the igniter 6. The igniter 6 includes a switching element and is configured to be turned on / off by a signal from an electronic control unit of an internal combustion engine (not shown).

  The secondary coil 52 of the ignition coil 5 is connected to the center electrode 21 of the ignition plug 2. The voltage limiting means 3 is connected to the secondary coil 52 in parallel with the spark plug 2. That is, a pair of Zener diodes 321 and 322 connected in series to each other are connected to the connection side of the secondary coil 52 with the spark plug 2. The pair of Zener diodes 32 are connected in series with each other by connecting the cathode of one Zener diode 321 to the anode of the other Zener diode 322. The anode of one Zener diode 321 is connected to the secondary coil 52, and the cathode of the other Zener diode 322 is grounded.

  The switching element 31 is connected between the connection point of the pair of Zener diodes 321 and 322 and the ground. The switching element 31 is also configured to be turned on / off by a signal from an electronic control unit of an internal combustion engine (not shown). When the switching element 31 is in the ON state, the upper limit value of the absolute value of the secondary voltage V2 applied to the spark plug 2 is the Zener voltage Vz1 of the Zener diode 321. On the other hand, when the switching element 31 is in the OFF state, the upper limit value of the absolute value of the secondary voltage V2 is the sum of the Zener voltage Vz1 of the Zener diode 321 and the Zener voltage Vz2 of the Zener diode 322, Vz1 + Vz2.

  The Zener voltages Vz1 and Vz2 can be set to Vz1 = 10 kV and Vz2 = 25 kV, respectively. In this example, a MOSFET (MOS field effect transistor) is used as the switching element 31 in the voltage limiting means 3, and an IGBT (insulated gate bipolar transistor) is used as the switching element constituting the igniter 6.

  As described above, the voltage limiting means 3 is configured such that the absolute value of the voltage V2 applied to the spark plug 2 does not exceed a predetermined voltage limit value, and the voltage limit value is set to the first stage S1 and the second stage described above. It is configured to be different from S2. As a specific means for that purpose, the voltage limit values Vh1 and Vh2 can be switched by turning the switching element 31 on and off. That is, in the first stage S1, the voltage limit value Vh1 can be set to Vz1 + Vz2 by turning off the switching element 31. In the second stage S2, the voltage limit value Vh2 can be set to Vz1 by turning on the switching element 31.

  The operation of the ignition device 1 provided with the voltage limiting means 3 configured as described above will be described below with reference to FIG. In the four graphs arranged side by side in the figure, the horizontal axis is the time axis. The graph with the symbol IGt on the left of the vertical axis shows the igniter 6 on / off, the SW graph shows the switching element 31 on / off, the V2 graph shows the change in the secondary voltage V2, and the Iz The graph shows changes in the value of the current flowing through the Zener diode 321 on the side close to the secondary coil 2.

  First, when the switching element of the igniter 6 is turned on, a current flows through the primary coil 51. Thereafter, when the igniter 6 is turned off, the energization to the primary coil 51 is cut off. Accordingly, an induced electromotive force is generated in the secondary coil 52, and the secondary voltage V2 is applied between the center electrode 21 and the ground electrode 22 of the spark plug 2. This electrical energy causes an initial discharge between the electrodes of the spark plastic 2. The portion indicated by P1 in the graph of V2 in FIG. 2 represents this first discharge voltage portion.

  In this example, the capacitive discharge first generated in the spark discharge gap G of the spark plug 2 due to the electric energy supplied from the ignition coil 5 to the spark plug 2 due to the on / off of the igniter 6 once. This is the first discharge described above.

  Here, in the first stage S1 until the end of the first discharge voltage section, the switching element 31 in the voltage limiting means 3 is in an OFF state. Therefore, the voltage limiting means 3 sets the upper limit value (voltage limit value Vh1) of the absolute value of the voltage V2 applied to the spark plug 2 to Vz1 + Vz2 as described above. Therefore, the first discharge has a somewhat high discharge voltage. Therefore, the first discharge can be surely generated.

  After the end of the first discharge voltage section, the switching element 31 of the voltage limiting means 3 is turned on. Thus, in the second stage S2, as described above, the voltage limiting means 3 sets the upper limit value (voltage limit value Vh2) of the absolute value of the voltage applied to the spark plug 2 to Vz1 as described above. This voltage Vz1 is smaller than the voltage limit value Vh1 (= Vz1 + Vz2) in the first stage S1. Therefore, the re-discharge occurring in the second stage S2 can reduce the discharge voltage.

  That is, in the second stage S2, inductive discharge occurs between the electrodes of the spark plug 2, but when the discharge blows out, capacitive discharge and inductive discharge occur again. Points P2, P3, and P4 in the graph of V2 in FIG. 2 represent this capacity discharge (re-discharge). By repeating this blow-off and re-discharge, even if the first discharge does not ignite, it is possible to ignite the gas by re-discharge. However, this re-discharge voltage is suppressed to the voltage limit value Vh2 or less. Thereby, the opportunity of ignition in 2nd step S2 can be ensured, suppressing the electrode consumption of the spark plug 2. FIG.

Next, the function and effect of this example will be described.
The voltage limiting means 3 is configured so that the absolute value of the voltage applied to the spark plug 2 does not exceed a predetermined voltage limiting value. That is, a voltage is applied between the electrodes of the spark plug 2 by the electrical energy supplied from the ignition coil 5 to the spark plug 2, but this voltage can be made lower than the voltage limit value. The voltage limit value is different between the first stage S1 and the second stage S2. Thereby, the discharge voltage of the spark plug 2 can be sufficiently reduced in each of the first stage S1 and the second stage S2.

The voltage limit value Vh2 in the second stage S2 is lower than the voltage limit value Vh1 in the first stage S1. That is, the voltage limit value Vh2 of the second stage S2 can be lowered while maintaining the voltage limit value Vh1 of the first stage S1 high to some extent.
As a result, in the first stage S1, the discharge voltage portion first generated in the spark plug 2 by the electric energy supplied to the spark plug 2 can be generated at a somewhat high voltage. Therefore, a spark discharge can be generated in the spark discharge gap G without causing dielectric breakdown in a portion other than the spark discharge gap G between the center electrode 21 and the ground electrode 22. That is, the first discharge can be surely generated, and as a result, misfire of the internal combustion engine can be prevented.
On the other hand, in the second stage S2, it is possible to reduce the voltage of re-discharge, which is a capacity discharge that can be repeatedly continued after the first discharge. Thereby, electrode consumption of the spark plug 2 due to repeated re-discharge can be suppressed.

  Further, the voltage limiting means 3 is configured so that the voltage limit value can be switched and set between two different values Vh1 and Vh2. Therefore, the voltage limit value Vh1 of the first stage S1 and the voltage limit value Vh2 of the second stage S2 lower than that can be easily set. Further, since the voltage limiting means 3 is provided on the secondary coil 51 side, the voltage limiting value Vh1 of the first stage S1 and the voltage limiting value Vh2 of the second stage S2 can be set more accurately.

  Further, since the voltage limiting means 3 includes the switching element 31 and the two Zener diodes 321 and 322, the voltage limiting values Vh1 and Vh2 can be easily switched and set accurately. Further, since the Zener diodes 321 and 322 are used, the voltage limit values Vh1 and Vh2 can be set finely.

  The two Zener diodes 321 and 322 are connected in series with each other, and the switching element 31 is connected to the connection point. Therefore, the electric energy emitted from the voltage limiting means 3 can be dispersed and emitted by the two Zener diodes 321 and 322. That is, the heat generated due to the discharge of electrical energy can be distributed to a plurality of Zener diodes. For this reason, heat generation in each part is suppressed, and the heat dissipation means can be easily downsized or eliminated. In addition, since the withstand voltage of each of the Zener diodes 321 and 322 can be reduced, it is easy to realize downsizing and cost reduction of the device. That is, it is easy to reduce the size and cost of the device as compared with the ignition device 10 according to Example 2 described later.

  The two Zener diodes 321 and 322 can be integrated into a package component. Then, by connecting the three terminals provided on the package component to the secondary coil 52, the switching element 31, and the ground, a part of the voltage limiting means 3 can be configured. In this case, the voltage limiting means 3 can be further reduced in size, and the ignition device 1 as a whole can be more easily reduced in size.

  As described above, according to this example, it is possible to provide an ignition device that can effectively suppress the electrode consumption of the spark plug while ensuring the ignitability.

(Example 2)
This example is an example of the ignition device 10 in which the configuration of the voltage limiting means 30 is different from that of the voltage limiting means 3 in the ignition device 1 according to the first embodiment, as shown in FIG.
That is, in the ignition device 10 of this example, the voltage limiting means 30 is constituted by two switching elements 313 and 314 and two Zener diodes 323 and 324. More specifically, a series body in which one switching element 313 (314) and one Zener diode 323 (324) are connected in series is connected in parallel to the spark plug 2, thereby providing a voltage. Limiting means 30 is configured. The two Zener diodes 323 and 324 have different Zener voltages Vz3 and Vz4.

  For example, the Zener voltage Vz4 of the second Zener diode 324 is set lower than the Zener voltage Vz3 of the first Zener diode 323. Then, in the first stage S1 until the first discharge voltage section is finished, the first switching element 313 is turned on and the second switching element 314 is turned off. Thereby, in 1st step S1, voltage limit value Vh1 can be set to Vz3. Then, in the second stage S2 after the end of the first discharge voltage section, the first switching element 313 is turned off and the second switching element 314 is turned on. Thereby, in 2nd step S2, voltage limit value Vh2 can be set to Vz4. That is, the voltage limit value Vh2 in the second stage S2 can be made lower than the voltage limit value Vh1 in the first stage S1. At this time, the second switching element 314 may be turned on while the first switching element 313 is turned on so that the switching can be reliably performed.

Others are the same as in the first embodiment. Of the reference numerals used in the drawings relating to this example, the same reference numerals as those used in the first embodiment represent the same components as in the first embodiment unless otherwise specified.
Also in this example, like the first example, it is possible to provide an ignition device that can effectively suppress the electrode consumption of the spark plug while ensuring the ignitability.

  The ignition device may employ various configurations other than the first and second embodiments. For example, the voltage limiting means can be provided on the primary side of the ignition coil. In this case, by making the upper limit value of the primary voltage variable, it is possible to control the upper limit value of the absolute value of the voltage applied to the spark plug in the first stage and the second stage. In addition, voltage limiting means can be provided in the spark plug.

  Further, the constant voltage element in the voltage limiting means is not limited to the Zener diode as shown in the first and second embodiments, and for example, an avalanche diode or a varistor can be used. Further, the voltage limiting means is not limited to the configuration including the constant voltage element and the switching element. Further, the switching element in the voltage limiting means is not limited to the MOSFET but may be, for example, an IGBT. Moreover, the switching element which comprises an igniter is not restricted to IGBT, For example, it is good also as MOSFET etc.

1, 10 Ignition device 2 Spark plug 21 Center electrode 22 Ground electrode 3, 30 Voltage limiting means 5 Ignition coil 51 Primary coil 52 Secondary coil S1 First stage S2 Second stage Vh1 (first stage) voltage limit value Vh2 (Second stage) voltage limit value

Claims (5)

An ignition coil (5) having a primary coil (51) and a secondary coil (52) magnetically coupled to the primary coil (51);
A spark plug (2) for generating a discharge spark between the electrodes by applying a voltage between the center electrode (21) and the ground electrode (22) based on the magnetic energy stored in the ignition coil (5); ,
Voltage limiting means (3, 30) for limiting the absolute value of the voltage (V2) applied between the electrodes of the spark plug (2) by the electrical energy supplied from the ignition coil (5) so as not to exceed a predetermined voltage limit value. )
The voltage limiting means (3, 30) determines the voltage limit value until the discharge voltage portion first generated in the spark plug (2) by the electrical energy supplied to the spark plug (2) is terminated. The voltage limit value of the second stage (S2) is different from the voltage limit value (Vh1) of the first stage (S1), which is different between the first stage (S1) and the subsequent second stage (S2). An ignition device (1, 10) characterized in that (Vh2) is set lower.   In the ignition device (1, 10) according to claim 1, the voltage limiting means (3, 30) can switch and set the voltage limit value between two different values (Vh1, Vh2). An ignition device (1, 10) characterized in that it is configured as follows.   The ignition device (1, 10) according to claim 2, wherein the voltage limiting means (3, 30) is provided on the secondary coil (52) side. .   The ignition device (1, 10) according to claim 2 or 3, wherein the voltage limiting means (3, 30) includes a switching element (31, 313, 314) and a plurality of constant voltage elements (321, 322, 323, 324). An ignition device (1, 10) characterized by comprising:   The ignition device (1, 10) according to claim 4, wherein the plurality of constant voltage elements (321, 322) are connected in series to each other, and the switching element (31) is a pair connected in series to each other. The voltage regulator (3, 30) is connected in parallel with the spark plug (2), and is connected to a connection point of the constant voltage elements (321, 322). (1, 10).

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