JPH02197300A - Vehicle generator provided with disconnection indicating function - Google Patents

Abstract

PURPOSE:To alarm occurrence of abnormality by detecting overvoltage to be generated upon interruption of voltage supply to a feeder line due to disconnection and then turning a field current interrupting means off, lighting an indication lamp. CONSTITUTION:Voltage control section A performs such control as overvoltage is generated upon occurrence of disconnection in wiring M. The overvoltage is detected and generation of power is stopped. Consequently, an indication lamp is lighted to alarm a driver. Generation of power is stopped by turning a field current interrupting transistor 10 inserted in a path for feeding field current to a field coil 3 OFF.

Description

[Detailed description of the invention] [Industrial application field]

The present invention relates to a situation in which the battery is discharged without the user noticing that a disconnection has occurred in the vehicle power generator.

[Conventional technology]

A vehicle is equipped with a generator driven by an engine, and the generated voltage is controlled to a predetermined value. FIG. 2 shows a conventional vehicle power generator. In Figure 2, A is the voltage control section, E is the power generation display section, F, H, K are the connection points, G is the generator section, L is the electric load, M is the wiring from the rectifier output point to the power supply line, N is the neutral point, S is the rectifier circuit section,
1 is a battery, 2 is a key switch, 3 is a field coil, 4
is a diode, 5 is a resistor, 6 is a diode, 7 is a voltage control transistor, 8 is a resistor, 9 is a voltage detection circuit, 33
35 is a resistor, 36 is a diode, 37 is a capacitor, 3rd is a Zener diode for reference voltage, 39 is a resistor, 40 is a transistor for detecting power generation, 4I is a transistor for lighting a power generation display lamp, 42 is a resistor, 43 is a power generation display A power generation display lamp is a means, 44 to 46 are diodes, and 47 is a power supply line. When the key switch 2 is turned on, a current flows through the path of the battery → the key switch 2 → the diode 4 → the resistor 5 → the resistor 8 → the base emitter of the voltage control transistor 7, and the voltage control transistor 7 is turned on. Then, battery 1 → key switch 2 → diode 4 →
Since a current flows through the field coil 3 along the path of the resistor 5 → field coil 3 → voltage control transistor 7, the generator section G generates electricity. The generated voltage is rectified by the rectifier circuit section S, and the rectifier circuit section S is configured to output two rectified outputs. 2 of the rectifier circuit section S is used to supply power to the electric load and the battery 1.
From one of the two rectified output points, that is, the connection point H,
This is done via a wiring M to a connection point K with the power supply line 47. In order to operate an electrical load normally, the supplied voltage needs to be controlled to be maintained at a predetermined value. The voltage control section A performs this control. In the voltage control section A, the generated voltage is derived from the point F which is not connected to supply power to the electric load or the battery 1 among the two rectification output points of the rectification circuit section S, that is, from the connection point F, By applying this to the voltage detection circuit 9, the generated voltage is detected. Then, the degree of conductivity of the voltage control transistor 7 is controlled in accordance with the detection signal, and the current of the field coil 3 is controlled. As a result, the generated voltage will be controlled. Note that since the generated voltage is controlled to be slightly higher than the voltage of the battery 1, the diode 4 is reverse biased after starting. The power generation display section E detects the voltage at the neutral point N of the generator section G and displays whether or not power is being generated. As explained below, the power generation display lamp 43 is turned off during power generation and turned on when power is not being generated. During power generation, a voltage appears at the neutral point N (eg, about 12V). This voltage is divided by resistors 33 and 34. The Zener voltage of the reference voltage Zener diode '38 is selected so that it is turned on by the aforementioned partial voltage during power generation. When the reference voltage Zener diode 3B turns on, the power generation detection transistor 40 turns on → the power generation display lamp lighting transistor 41 turns off, and the power generation display lamp 4 turns on.
3 is off. When power is not being generated, the partial voltage is zero, so the reference voltage Zener diode 38 is turned off → the power generation detection transistor 40 is turned off → the power generation display lamp lighting transistor 4
1 is turned on, and the power generation display lamp 43 lights up. The capacitor 37 is inserted so as not to react to instantaneous voltage fluctuations caused by noise or the like. Note that the diode 6 is for providing a path for discharging the electromagnetic energy of the field coil 3, and the diodes 45 and 46 are for preventing reverse voltage (surge, etc.) from being applied to the transistor. belongs to.

[Problem to be solved by the invention]

(Problem) However, in the above-mentioned conventional technology, the rectifier circuit section S
If a disconnection occurs in the wiring M from the connection point H to the connection point K to the power supply line 47, which supplies power to the electric load and the battery 1 out of the two rectified output points, the problem will occur without your knowledge. There was a problem that the battery 1 was consumed. (Explanation of the problem) In Fig. 2, if a disconnection occurs in the wiring M, power will no longer be supplied from the generator section G to the electrical load, and the electrical load will be exclusively supplied with power from the battery 1. . However, no warning is issued from anywhere to notify the driver that power has started to be supplied exclusively to the electric load from the battery 1. Therefore, since the driver does not notice this, the situation progresses without any measures being taken, and the battery 1 gradually wears out as time passes. Note that the power generation display section E indicates that the generator section G has not failed, and voltage continues to be generated at the neutral point N, so the power generation display lamp 43 remains off, alerting the driver. I don't do anything. An object of the present invention is to solve the above-mentioned problems.

[Means to solve the problem]

In order to solve the above-mentioned problem, the present invention takes the following measures in order to turn on the power generation indicator lamp 43 to alert the driver when a disconnection occurs in the wiring M in the above-mentioned part. Ta. That is, the vehicle power generation device with a disconnection display function of the present invention includes a voltage control section that detects the voltage of a power supply line connected to an electric load or a battery, an overvoltage detection section that detects overvoltage of the generated voltage, and an overvoltage detection section that detects an overvoltage of the generated voltage. an overvoltage detection signal storage section that stores the signal until the key switch is turned off; a field current cutoff means that is inserted into the field current path and is turned off by the overvoltage detection signal from the overvoltage detection signal storage section; It was decided to include a power generation display means that lights up the special number.

[For production]

When a predetermined generated voltage controlled by the voltage control section is supplied to the power supply line, the field current interrupting means is kept on and constitutes a part of the path for supplying the field current. However, when the generated voltage is no longer supplied to the power supply line due to a disconnection, the voltage control section detects the battery voltage (which is lower than the generated voltage) and performs control. This control increases the generated voltage! IJ? Become a wholesaler. As a result, the generated voltage becomes an overvoltage, the overvoltage detection section generates an overvoltage detection signal, and the signal is stored in the overvoltage detection signal storage section. Based on this stored detection signal, the field current interrupting means is turned off and power generation is stopped. When power generation is stopped, the power generation indicator lamp lights up to notify the driver that an abnormality has occurred. Note that since the detection signal is stored until the key switch is turned off, power generation will also be stopped until the key switch is turned off, but this was done to avoid restarting power generation without investigating the cause of the abnormality. This is because it is not desirable.

【Example】

Embodiments of the present invention will be described in detail below with reference to the drawings. (Summary of Configuration and Operation) FIG. 1 shows a vehicle power generation device with an overvoltage protection device according to an embodiment of the present invention. The same reference numerals as in FIG. 2 correspond to those in FIG. B is an overvoltage protection section, C is an overvoltage detection signal storage section, D is an overvoltage detection section, and P is a connection point.
10 is a field current cutoff transistor, 11, 12.13
is a resistor, 14 is a transistor, 15 is a Zener diode, 16 is a Sirisk, 1 to 20 are resistors, 21 is a capacitor, 22 is a transistor, 23 is a Zener diode, 24.25 is a resistor, 26 is an overvoltage detection transistor, 27 is a Zener diode for reference voltage, 28 to 30 are resistors, 31 is a capacitor, and 32 is a variable resistor. In the present invention, the generated voltage to be applied to the voltage detection circuit 9 is taken in from the power supply line 47 which is also connected to the battery 1. That is, in the past, it was taken in from the connection point F, but in the present invention, it was taken in from the connection point P. As a result, if a disconnection occurs in the wiring M, the voltage control section A will automatically control the generated voltage to become an overvoltage, but the overvoltage will be detected and the power generation will be stopped. Since the power generation display lamp 43 lights up when power generation stops, this lighting is intended to alert the driver. To stop power generation, a field current cutoff transistor 10, which serves as a field current cutoff means, is inserted into the path through which the field current flows to the field coil 3, and the field current is cut off when the generated voltage becomes an overvoltage. This is done by turning off the transistor 10. An overvoltage detection section detects whether or not the generated voltage has become overvoltage. The overvoltage detection signal storage section C stores the detection signal. The memory operation is maintained until the key switch 2 is turned off. In response to the signal from the overvoltage detection signal storage section C, the field current cutoff transistor 1 of the overvoltage protection section B
On/off of 0 is controlled. (Operation at startup) When the key switch 2 is turned on, a current flows through the path of battery 1 → key switch 2 → diode 44 → resistor 17 → Zener diode 15 → Hess 3 emitter of transistor 14, and transistor 14 is turned on. . Therefore,
Battery 1 → Key switch 2 → Diode 4 → Resistor 5 →
Emitter and base of field current cutoff transistor 10 →
A current flows through the path from the resistor 12 to the transistor 14, and the field current cutoff transistor 10 is turned on. Further, the voltage control transistor 7 is turned on by a current flowing through the path from the terminal 1 to the key switch 2 to the connection point P to the resistor 8 to the hess 3 emitter of the voltage control transistor 7. Therefore, the field current flows through the path of battery 1 → key switch 2 → diode 4 → resistor 5 → field current cutoff transistor 10 → field coil 3 → voltage control transistor 7, and the generator section G starts generating power. do. After starting, the diode 4 is reverse biased as in the conventional case. (Normal operation - when there is no disconnection in the wiring M) The generated voltage derived from the connection point F, which is one rectification output point of the rectifier circuit section S, is applied to the field coil 3 and overvoltage is detected. It is also applied to the parts. Overvoltage detection in the overvoltage detection section is performed by connecting the generated voltage to resistor 2.
9. Variable resistance 32. This is done by comparing the voltage divided by the resistor 30 and the Zener voltage of the reference voltage Zener diode 27. At normal voltage, the partial voltage is smaller than the Zener voltage, so
The reference voltage Zener diode 27 remains off. Therefore, the overvoltage detection transistor 2G is also off. That is, no overvoltage detection signal is generated. When the overvoltage detection transistor 26 is off, the Zener diode 23, the transistor 22, and the cyrisk 16 of the overvoltage detection signal storage section C are also off. Therefore, the Zener diode 15.
Transistor 14 and field current cutoff transistor 1
0 remains on, and the generated voltage is controlled to a predetermined value by the voltage control section A in the same manner as in the conventional case. Note that since power generation is in progress, the power generation display lamp 43 of the power generation display section E is off. (Operation when wire M is disconnected) At this time, the voltage taken into the voltage detection circuit 9 via the connection point P is the voltage of the battery 1. However, in general, the output voltage of the generator section G (determined by the voltage comparison reference value in the voltage detection circuit 9, etc.) is set to be slightly higher than the voltage of the battery 1. A voltage lower than the voltage will be applied. Then, the voltage detection circuit 9 controls the voltage control transistor 7 to increase the voltage of the generator section G. However, since the increased generated voltage is not transmitted to the connection point P, the voltage detection circuit 9 continues to control to increase the generated voltage. As a result, the generated voltage becomes an overvoltage. Since this overvoltage is derived from the connection point F and applied to the overvoltage detection section, the overvoltage detection section operates as follows to generate an overvoltage detection signal. That is, when the generated voltage becomes an overvoltage, the above-mentioned divided voltage at the overvoltage detection section also increases and exceeds the Zener voltage of the reference voltage Zener diode 27. Then, the reference voltage Zener diode 27 is turned on, and the overvoltage detection transistor 26 is turned on. Note that the capacitor 31 is inserted to prevent the reference voltage Zener diode 27 from turning on even if the voltage becomes excessively large momentarily. That is, this is to prevent malfunctions due to noise. When the overvoltage detection transistor 26 is turned on, the Zener diode 23 in the overvoltage detection signal storage section C is also turned on.
Transistor 22 turns on. As a result, a voltage is developed across the resistor 20, which turns on the cyrisk 16. Since the connection configuration is such that the current to the SIRISK 16 can be supplied not only from the rectifier circuit section S but also from the battery 1, it continues to flow until the key switch 2 is turned off even when power generation is stopped. Immediately, the detection of overvoltage takes the form of keeping Cyrisk 16 on,
It continues to be memorized until the key switch 2 is turned off. Note that the capacitor 21 also has a si risk of 1 due to noise.
This is to prevent 6 from malfunctioning. When the thyrisk 16 turns on, the Zener diode 15 in the overvoltage protection section B turns from on to off. Then, the base current is no longer supplied to the transistor 14, and the transistor 14 is also turned off. As a result, the field current cutoff transistor 10 is turned off. The reason why the field current cutoff transistor 10 is turned off by a signal from the overvoltage detection signal storage section C (that is, by turning on the Cyrisk 16) is as follows. That is, if power generation is restarted without investigating the cause of the overvoltage (one of which is the disconnection of the wiring M), there is a high possibility that the overvoltage will occur again. Therefore, it is safer to continue stopping power generation until the key switch is turned off for inspection or the like. By turning off the field current cutoff transistor 10, the field current is cut off and power generation by the generator section G is stopped. When power generation is stopped, the power generation display lamp 43 of the power generation display section E lights up to alert the driver.

【Effect of the invention】

According to the present invention as described above, the following effects are achieved. In the present invention, the generated voltage applied to the voltage detection circuit in the voltage control section of the generator is taken from the power supply line to the electric load and battery, and the generation is stopped immediately when the generated voltage becomes overvoltage. Therefore, if a break occurs in the wiring from the output point of the generator's rectifier circuit to the power supply line to the electrical load or battery, power generation will be stopped and the power generation indicator lamp will light up to alert the driver. I can do it. As a result, it has become possible to avoid a situation where the battery is consumed unknowingly.

[Brief explanation of the drawing]

Figure 1: Vehicle power generator with disconnection display function according to an embodiment of the present invention Figure 2: In the diagram of a conventional vehicle power generator, A is a voltage control section, B is an overvoltage protection section, and C is an overvoltage detection signal. Storage section, D is overvoltage detection section, E is power generation display section, F, H, K, P are connection points, G is generator section,
L is the electrical load, M is the wiring from the rectifier output point to the power supply line, N is the neutral point, S is the rectifier circuit section, 1 is the battery, 2 is the key switch, 3 is the field coil, 4 is the diode, and 5 is the Resistor, 6 is a diode, 7 is a voltage control transistor,
8 is a resistor, 9 is a voltage detection circuit, 10 is a transistor for field current cutoff, 11, 12, 13 is a resistor, 14 is a transistor, 15 is a Zener diode, 16 is a thyrisk,
1 to 20 are resistors, 21 is a capacitor, 22 is a transistor, 23 is a Zener diode, 2425 is a resistor, 26 is a transistor for overvoltage detection, 27 is a Zener diode for reference voltage, 28 to 30 are resistors, 31 is a capacitor, 32 is a variable resistor, 33 to 35 are resistors, 3
6 is a diode, 37 is a capacitor, 38 is a Zener diode for reference voltage, 39 is a resistor, 40 is a transistor for detecting power generation, 41 is a transistor for lighting a power generation display lamp, 42 is a resistor, 43 is a power generation display lamp, 44 to 46
is a diode, and 47 is a power supply line.

Claims (1)

[Claims] A voltage control unit that uses the voltage of the power supply line connected to the electric load or battery as the detection voltage, an overvoltage detection unit that detects overvoltage of the generated voltage, and an overvoltage detection signal memory that stores the overvoltage detection signal until the key switch is turned off. , a field current cutoff means inserted into the field current path and turned off by an overvoltage detection signal from the overvoltage detection signal storage section, and a power generation display means that lights up when power generation is stopped. A vehicle power generator with a disconnection display function.