JP6842882B2 - Speed change display device - Google Patents

Description

The present invention relates to a shift stage display device including a processor that controls the display of the shift stage switching position of the transmission.

Patent Document 1 discloses a shift stage display device including a processor that controls the display of the shift stage switching position of the transmission.

Japanese Unexamined Patent Publication No. 2010-230072

By the way, in the speed change display device of Patent Document 1, if the battery that supplies electric power to the processor and the processor are always electrically connected, when the ignition switch is turned off, the battery is used. Leakage current flows through the processor, which increases battery consumption when the accessory is off.

The present invention has been made in view of this point, and an object of the present invention is to suppress battery consumption in an accessory off state.

In order to achieve the above object, the present invention is characterized in that the connection between the battery and the processor is cut off when the accessory is off.

Specifically, the first invention targets a shift stage display device including a processor that controls the display of the shift stage switching position of the transmission, and has taken the following solutions.

That is, the first invention further includes an internal switch element that can switch between a connection state for connecting the battery that supplies power to the processor and the processor and a cutoff state for cutting off the connection, and the processor is an ignition. The signal output device outputs when the switch is in the accessory on state, while the output is stopped when the ignition switch is in the accessory off state. When a communication signal is received, the switching position is displayed. While performing control, when the communication signal is not received for a predetermined time, an off signal is output from the off signal output terminal, and when the output of the communication signal is started when the internal switch element is in the cutoff state, the internal switch The internal switch element maintains the connected state until the element is switched from the cutoff state to the connected state, and then the off signal is output from the processor, and when the off signal is output from the processor, the internal switch element is released. It is characterized in that it is configured to be in a shut-off state.

The second invention includes, in the shift stage display device according to the first invention, a bipolar transistor for maintaining a connection state in which the base is connected to the off signal output terminal and the off signal is output to cause nonconductivity. The communication signal is output from the collector of the communication signal output bipolar transistor, and the base of the internal switch element is connected to the collector of the connection state maintaining bipolar transistor and the communication signal output bipolar transistor. It is characterized in that it is composed of a bipolar transistor for a switch.

According to the third invention, in the shift stage display device according to the second invention, the internal switch element is a pnp type transistor, and the base of the internal switch element is a collector of the bipolar transistor for maintaining the connection state and the above. In addition to the collector of the bipolar transistor for communication signal output, when the battery is connected to the emitter of the internal switch element, a current path through which current flows from the battery to the base and emitter of the internal switch element is connected. It is characterized by being.

The fourth invention is characterized in that, in the shift stage display device according to the third invention, a capacitor is provided in the current path.

According to the first and second inventions, when the ignition switch is turned off and the output of the communication signal by the signal output device is stopped for a predetermined time, the processor outputs an off signal and the connection between the battery and the processor is internal. Since it is cut off by the switch element and no leakage current flows from the battery to the processor, battery consumption in the accessory off state is suppressed.

Further, when the ignition switch when the internal switch element is in a cutoff state is the accessory ON state, an internal switching device is switched to the connected state from the disconnected state, then the connection state is maintained. Therefore, the battery continuously supplies power to the processor with the accessories on.

According to the third invention, when an external switch element is provided between the battery and the internal switch element to connect the two in the accessory on state and to cut off the connection between the two in the accessory off state, the ignition switch becomes an accessory. When the accessory is switched from the off state to the accessory on state, the current from the battery flows into the current path through the base-emitter of the internal switch element, so that the collector-emitter of the internal switch element becomes conductive and the battery The power supply to the processor is started. Therefore, even if it takes a long time for the signal output device to start outputting the communication signal after the ignition switch is turned on, the processor can be started quickly, and the processor can be started after the ignition switch is turned on. It is possible to shorten the time required for the control of the display of the switching position to be started by.

According to the fourth invention, since the current does not flow from the battery to the current path when the charging of the capacitor is completed, the shift stage display is performed even when the external switch element as described above is not interposed between the battery and the internal switch element. The device can be used. Therefore, the versatility of the shift stage display device is improved as compared with the case where the capacitor is not provided in the current path.

It is a schematic circuit diagram which shows a part of the electric system of the automobile provided with the shift stage display device which concerns on Embodiment 1 of this invention. It is a circuit diagram which shows the concrete structure around the 2nd switch element. FIG. 1 is a view corresponding to FIG. 1 of the second embodiment. FIG. 2 is a view corresponding to FIG. 2 of the second embodiment.

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

(Embodiment 1)
FIG. 1 shows a part of an electric system of an automobile provided with a shift stage display device 1 according to the first embodiment of the present invention. This automobile has an ignition switch 3 that switches between an accessory off state, an accessory on state, an ignition off state, and an ignition on state by operating an ignition key (not shown), and a light switch 5 that turns on and off lights such as headlights. And, a shift lever 7 for switching the shift stage of the transmission is mounted. The state of the ignition switch 3, the on / off state of the light switch 5, and the switching state of the shift stage of the shift lever 7 are input to the first CPU (Central Processing Unit) 9. The first CPU 9 is connected to, for example, a 12V battery 13 that supplies electric power to the first CPU 9 and the second CPU 11 described later. The first CPU 9 operates by receiving electric power from the battery 13 when the ignition switch 3 is in the accessory-on state. Specifically, the first CPU 9 has a plurality of first LEDs, which will be described later, based on the on / off state of the light switch 5 and the switching state of the shift stage of the shift lever 7 when the ignition switch 3 is in the accessory on state. The first control signal CS1 for controlling the (Light Emitting Diode) 15 and the second control signal CS2 for controlling a plurality of second LEDs 17 described later are output. The second control signal CS2 is a pulse signal. The first control signal CS1 is input to the base of the first npn type transistor 19 whose emitter is grounded. When the first control signal CS1 is output from the first CPU 9, the first npn type transistor 19 conducts. The second control signal CS2 is input to the base of the second npn type transistor 21 as a communication signal output bipolar transistor having a grounded emitter. When the second control signal CS2 is output from the first CPU 9, the conductive state and the non-conducting state of the second npn type transistor 21 are repeatedly switched, and the communication signal TS is output from the collector of the second npn type transistor 21. The first CPU 9, the first npn-type transistor 19, and the second npn-type transistor 21 are arranged inside the meter unit and constitute a signal output device 23 that outputs a communication signal TS.

The speed change display device 1 includes a first battery connection terminal CTE1, a second battery connection terminal CTE2, a first communication terminal TTE1, and a second communication terminal TTE2. The first battery connection terminal CTE1 is connected to the output of the battery 13. The second battery connection terminal CTE2 is connected to the output of the battery 13 via the first switch element 25 that conducts when the light switch 5 is on. The first communication terminal TTE1 is connected to the collector of the first npn type transistor 19. The second communication terminal TTE2 is connected to the collector of the second npn type transistor 21 and receives the communication signal TS.

The speed change display device 1 includes a plurality of first LEDs 15 that illuminate the dial of the meter, a second LED 17 that illuminates the indicator panel, and a second CPU 11 as a processor that controls the plurality of second LEDs 17 via an output transistor 26. There is. The first LED 15 is arranged so as to illuminate the dial of the meter, and the second LED 17 is a plurality of characters (P, R,) for displaying the switching position of the transmission stage on the indicator panel around the shift lever 7. It is arranged so as to illuminate a translucent display area formed in the shape of N, D, M, +,-). Therefore, the second CPU 11 controls the display of the switching position of the shift stage of the transmission by controlling the plurality of second LEDs 17.

The second CPU 11 includes a first power supply terminal STE1, a second power supply terminal STE2, and a communication signal reception terminal RTE. Between the first power supply terminal STE1 and the first battery connection terminal CTE1, in order from the first battery connection terminal CTE1, a first diode 27, a second switch element 29 as an internal switch element, and, for example, 5V A stabilization circuit 31 that outputs a stable voltage is connected. The second power supply terminal STE2 is connected to the second battery connection terminal CTE2 via the second diode 33. The communication signal receiving terminal RTE is connected to the second communication terminal TTE2 to receive the communication signal TS. Further, when the second CPU 11 does not receive the communication signal TS from the communication signal receiving terminal RTE for a predetermined time, that is, when the communication signal TS is not output for a predetermined time by the signal output device 23, the second CPU 11 outputs the off signal OS from the off signal output terminal OTE. Output.

As shown in FIG. 2, the second switch element 29 is composed of a pnp type transistor (bipolar transistor) as a switch bipolar transistor, and disconnects the connection state of connecting the battery 13 and the second CPU 11 and the connection. It can be switched to the cutoff state depending on the presence or absence of the base current. The base of the second switch element 29 is the second communication terminal TTE2, that is, the second npn type transistor 21 via the first resistor 35, the backflow prevention diode 37, and the second resistor 39 in this order from the second switch element 29 side. It is connected to the collector of the second switch element 29 and is connected to the emitter of the second switch element 29 via the third resistor 41. Therefore, when the output of the communication signal TS by the signal output device 23 starts while the second switch element 29 is in the cutoff state, the second switch element 29 is switched from the cutoff state to the connected state. Further, the base of the second switch element 29 maintains the connected state of the second switch element 29 until the off signal OS is output from the second CPU 11 after the second switch element 29 is switched from the cutoff state to the connected state. It is connected to the maintenance circuit 43 via the first resistor 35. In the maintenance circuit 43, the fourth resistor 45 connected in series with the first resistor 35, the collector is connected to the terminal on the anti-first resistor 35 side of the fourth resistor 45, and the emitter is grounded. It includes a third npn-type transistor 47 as a bipolar transistor for maintaining the connection state. The base of the third npn type transistor 47 is connected to the emitter via the fifth resistor 49, and is connected to the output of the stabilization circuit 31 via the sixth resistor 51, and the seventh resistor 53. It is connected to the off signal output terminal OTE via.

Further, between the first communication terminal TTE1 and the second power supply terminal STE2, three pairs of LEDs in which two of the first LEDs 15 are connected in series with the second power supply terminal STE2 side as an anode are connected in parallel. Has been done.

Next, the operation of each part when the ignition switch 3 is switched between the accessory off state and the accessory on state with the light switch 5 turned on will be described.

When the ignition switch 3 is switched to the accessory on state when the ignition switch 3 is in the accessory off state, the first CPU 9 is activated and the output of the first control signal CS1 and the second control signal CS2 is started. As a result, the first npn type transistor 19 becomes conductive, a current flows from the battery 13 to the first LED 15 via the first switch element 25 and the second diode 33, and the first LED 15 lights up. Further, when the output of the second control signal CS2 is started, the second npn type transistor 21 is repeatedly switched between the conductive state and the non-conducting state, and the communication signal TS is output from the collector of the second npn type transistor 21. When the second npn type transistor 21 conducts, the second switch element 29 conducts, the power of the battery 13 is supplied from the first power supply terminal STE1 to the second CPU 11, the second CPU 11 starts, and the second LED 17 based on the communication signal TS Start control. Once the second switch element 29 is switched from the cutoff state to the connection state connecting the battery 13 and the second CPU 11, the connection state is subsequently maintained by the maintenance circuit 43. Therefore, power is continuously supplied from the battery 13 to the second CPU 11 in the accessory-on state.

After that, when the ignition switch 3 is switched from the accessory on state to the accessory off state, the first CPU 9 stops the output of the first control signal CS1 and the second control signal CS2. As a result, the first npn type transistor 19 becomes non-conducting, and the first LED 15 is turned off. Further, when a predetermined time elapses after the output of the second control signal CS2 is stopped, the second CPU 11 outputs the off signal OS via the off signal output terminal OTE. As a result, the third npn-type transistor 47 of the maintenance circuit 43 becomes non-conducting, the second switch element 29 becomes a cutoff state in which the connection between the battery 13 and the second CPU 11 is cut off, and the second CPU 11 stops operating. After that, even if the accessory off state continues, the connection between the battery 13 and the second CPU 11 is cut off by the second switch element 29, and no leak current flows from the battery 13 to the second CPU 11, so that the consumption of the battery 13 is suppressed. ..

Therefore, according to the first embodiment, since the second switch element 29 is composed of the pnp type transistor, it is not necessary to provide a booster circuit for making the base voltage higher than the emitter voltage as compared with the case where the second switch element 29 is composed of the npn type transistor. The circuit configuration can be simplified by a good amount.

(Embodiment 2)
FIG. 3 is a view corresponding to FIG. 1 of the second embodiment of the present invention. In the second embodiment, the third switch element 55 connects the battery 13 and the first battery connection terminal CTE1 of the speed change display device 1 in the accessory on state and cuts off the connection in the accessory off state. Is provided. Further, as shown in FIG. 4, one electrode of the capacitor 57 is connected between the first resistor 35 and the fourth resistor 45, and the other electrode of the capacitor 57 is grounded. Therefore, when the battery 13 is connected to the emitter of the second switch element 29 by conducting the third switch 55, the first resistor 35 and the capacitor 57 are the base-emitter of the second switch element 29 from the battery 13. It constitutes a current path 59 through which a current flows through the space.

Since the other configurations are the same as those in the first embodiment, the same configurations are designated by the same reference numerals and detailed description thereof will be omitted.

Therefore, according to the second embodiment, when the ignition switch 3 is switched from the accessory off state to the accessory on state, the current from the battery 13 enters the current path 59 via the base and the emitter of the second switch element 29. By flowing in, the collector-emitter of the second switch element 29 also conducts, and the supply of power from the battery 13 to the second CPU 11 is started. Therefore, the second CPU 11 can be started without waiting for the output of the communication signal TS by the signal output device 23, and the time required from when the ignition switch 3 is turned on to the start of the control of the second LED 17 by the second CPU 11. Can be shortened.

A resistor may be provided instead of the capacitor 57, but in the second embodiment, the capacitor 57 prevents the second switch element 29 from being destroyed when noise enters from the second communication terminal TTE2. it can. Further, since the current does not flow from the battery 13 to the current path 59 when the charging of the capacitor 57 is completed, the case where the third switch element 55 is not interposed between the battery 13 and the second switch element 29 as in the first embodiment. The speed change display device 1 can also be used. Therefore, the versatility of the shift stage display device 1 is improved as compared with the case where the capacitor 57 is not provided in the current path 59.

In the first embodiment, the second switch element 29 is composed of a pnp type transistor, but it may be composed of an npn type transistor. Further, the present invention is not limited to the bipolar transistor, and may be configured by a MOSFET (Metal Oxide Semiconductor Field Effect Transistor).

Further, in the first and second embodiments, the off-signal OS output by the second CPU 11 is input to the maintenance circuit 43, and the maintenance circuit 43 shuts down the second switch element 29. A signal for blocking the 29 may be directly input from the second CPU 11 to the second switch element 29.

Further, in the first and second embodiments, the second CPU 11 controls the second LED 17, but other types of light sources may be controlled.

Further, in the first and second embodiments, when the first control signal CS1 is output from the first CPU 9, the first npn type transistor 19 is made conductive, but the first control signal CS1 is used as a pulse signal and the first CPU 9 is used. When the first control signal CS1 is output from the first control signal CS1, the conductive state and the non-conducting state of the first npn type transistor 19 may be repeatedly switched. In such a case, the brightness of the first LED 15 may be controlled by controlling the duty ratio of the first control signal CS1.

The present invention is useful as a shift stage display device including a processor that controls the display of the shift stage switching position of the transmission.

1 Speed change display device 3 Ignition switch 11 2nd CPU (processor)
13 battery
21 Second npn type transistor (bipolar transistor for communication signal output)
23 Signal output device 29 2nd switch element (internal switch element , bipolar transistor for switch)
47th 3nd npn type transistor (bipolar transistor for maintaining connection state)
57 Capacitor 59 Current path TS Communication signal OS Off signal
OTE off signal output terminal

Claims (4)

It is a shift stage display device (1) equipped with a processor (11) that controls the display of the shift stage switching position of the transmission.
Further provided with an internal switch element (29) that can be switched between a connection state for connecting the battery (13) for supplying power to the processor (11) and the processor (11) and a cutoff state for cutting off the connection.
The processor (11) is output by the signal output device (23) when the ignition switch (3) is in the accessory on state, while the ignition switch (3) is in the accessory off state. When the communication signal (TS) whose output is stopped is received, the display of the switching position is controlled, while when the communication signal (TS) is not received for a predetermined time, the off signal (OS) is output from the off signal output terminal (OTE). Output,
When the output of the communication signal (TS) is started while the internal switch element (29) is in the cutoff state, the internal switch element (29) is switched from the cutoff state to the connected state, and then the processor ( The internal switch element (29) maintains the connected state until the off signal (OS) is output from 11), and when the off signal (OS) is output from the processor (11), the internal switch element (29) ) Is configured to be shut off. In the speed change display device according to claim 1,
The base is connected to the off-signal output terminal (OTE), and the connection state maintaining bipolar transistor (47) that becomes non-conducting when the off-signal (OS) is output is provided.
The communication signal (TS) is output from the collector of the communication signal output bipolar transistor (21).
The internal switch element (29) is composed of a switch bipolar transistor (29) whose base is connected to a collector of the connection state maintaining bipolar transistor (47) and a collector of the communication signal output bipolar transistor (21). A speed change display device characterized by being In the speed change display device according to claim 2,
The internal switch element (29) is a pnp type transistor.
In addition to the collector of the bipolar transistor (47) for maintaining the connection state and the collector of the bipolar transistor (21) for outputting the communication signal, the base of the internal switch element (29) is used as the emitter of the internal switch element (29). When the battery (13) is connected, a current path (59) through which a current flows from the battery (13) to the base and the emitter of the internal switch element (29) is connected. Speed change display device. In the speed change display device according to claim 3,
A speed change display device characterized in that a capacitor (57) is provided in the current path (59).

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