KR200174857Y1 - Communication device with inspections and electric control devices - Google Patents

Abstract

The present invention relates to a communication device between an inspection device and an electronic control device that prevents unnecessary signals from being transmitted to the outside by intermittently intermitting data transmission and fault signal thrust at the transmitting end of the K line using signals received on the L line. Constant voltage means for maintaining a signal at a constant potential, pull-up means for stabilizing the signal of the constant voltage means, first signal inverting means for inverting the signal of the pull-up means and applying it to the receiving end of the L line, and flowing from Filtering means (C1, C10, C100) for removing various noises, first dividing means for dividing a signal of the K line, first switching means switched in accordance with the signal of the first dividing means, and the first switching Second switching means switched according to the signal of the means, second signal inverting means for inverting the signal output from the data transmitting end, and a signal of the second signal inverting means. The third switching means switched accordingly, the fourth switching means switched according to the signal of the data transmitting end, the fifth switching means switched according to the signal of the fourth switching means, and the signal of the fifth switching means. And sixth switching means including a second voltage divider and switched by a signal of the first signal inverting means, and seventh switching means by which the six switching means are switched by a signal.

Description

Communication device between inspection device and electronic control device

The present invention relates to a communication device between the inspection device and the electronic control device, and more particularly, data transmission from the data transmission end of the electronic control device to the inspection device K line and a failure signal using a signal received from the L line of the inspection device. The present invention relates to a communication device between an inspection device and an electronic control device which prevents unnecessary signals from being transmitted to the outside by intermittent failure outputs to an output terminal.

In general, the communication between the electronic control device and the inspection device is to perform data communication through the communication cable line in accordance with the GST protocol.

The data communication is installed at an arbitrary position in the vehicle to detect the failure of the vehicle and receive the contents stored in the electronic control device as mutually promised data through the input / output device as shown in FIG. Users and maintenance workers can see the presence of the naked eye so that the maintenance of the correct failure site can be done easily and quickly.

However, in the conventional apparatus as shown in FIG. 2, the data transmission section of the electronic control apparatus shares data transmission to the inspection apparatus K line and the fault signal output to the fault signal output stage according to the state of the inspection apparatus L line. As a result, unnecessary signals are transmitted to the outside.

This eventually causes an increase in electromagnetic radiation (EMI), and damage to the electronic controller may occur due to external defects.

The present invention has been made to solve such a problem, and its purpose is to intercept data transmission and failure signal output of the electronic control device data transmission stage by using the signal received by the check device L line, thereby preventing unnecessary external transmission of the signal. To prevent it.

In order to achieve the above object, the present invention, in the communication device between the inspection device and the electronic control device, the constant voltage means is folded to the inspection device L line and maintains the signal of the L line at a constant electric potential, A pull-up means connected to stabilize the signal of the constant-voltage means, a first signal inverting means connected to the pull-up means and inverting a signal of the pull-up means and applied to the receiving end of the electronic control apparatus, and one side of the check device L line and K; Filtering means (C1, C10, C100) connected to the line and the fault signal output terminal, the other side of which is grounded to the case to remove various noises from the outside, and a first device connected to the inspection device K line to divide the signal of the K line. A voltage dividing means, a first switching means connected to the first voltage dividing means and switched according to a signal of the first voltage dividing means, and a first switching means connected to the first switching means. Second switching means switched according to the signal, second signal inverting means connected to the data transmitting end of the electronic control apparatus and inverting the signal output from the data transmitting end, and second signal inverting means connected to the second signal inverting means. A third switching means switched according to the signal of the electronic control apparatus, the fourth switching means connected to the data transmitting end of the electronic control apparatus and switched according to the signal of the data transmitting end, and connected to the fourth switching means and connected to a signal of the fourth switching means. And fifth dividing means connected to the fifth switching means and the second dividing means for dividing a signal of the fifth switching means, the fifth switching means being connected to the output terminal of the first signal inverting means. A sixth switching means switched by a signal of the signal, and a seventh switching means connected to the sixth switching means and the sixth switching means are switched by a signal. It characterized.

1 is a detailed circuit diagram showing an embodiment according to the communication device between the inspection device and the electronic control device of the present invention,

2 is a detailed circuit diagram showing a communication device between the conventional inspection device and the electronic control device.

* Explanation of symbols for main parts of the drawings

20, 90: partial pressure part 30: first switching part

40: second switching unit 1, 50: inverter

60: third switching unit 70: fourth switching unit

80: fifth switching part C1, C2, C10, C100: dec capacitor

110: sixth switching unit 120: seventh switching unit

Hereinafter, a preferred embodiment according to the present invention with reference to the accompanying drawings as follows.

As can be seen in Figure 1 one preferred embodiment according to the present invention is a capacitor (C1, C2, C10, C100), constant voltage unit (1), pull-up resistor (R1), voltage divider (20, 90) switching The unit 30, 40, 60, 70, 80, 110, 120, and the inverter (2, 50).

One side of the first capacitor C1 is grounded to the case, and the other side of the first capacitor C1 is connected to the check device L line to remove various noises introduced from the outside.

The constant voltage unit 1 includes a diode D2 having an anode terminal grounded and a diode terminal D1 connected to a cathode terminal of the diode D2 and a cathode terminal connected to an L line, The thrust signal is maintained at a constant potential.

The pull-up resistor (R1) is connected to the power supply terminal (V) on one side, and outputs a "high" signal when there is no connector connection on the L line of the inspection device. Output

The second capacitor C2 removes noise existing in the signal of the pull-up resistor R1.

One side of the first inverter 2 is connected to the receiving terminal of the electronic controller through the resistor R2, and inverts the signal of the pull-up resistor R1 to the receiving terminal.

One end of the third capacitor C10 is grounded to the case, and the other end of the third capacitor C10 is connected to the inspection device K line to remove various noises introduced from the outside.

The first voltage divider 20 is connected to the resistor R21 and the zener diode ZD having the anode terminal grounded in parallel, and divides the potential of the signal output from the checker K line to form a zener diode ZD as a constant voltage diode. Thrust with a signal of a constant potential.

In the first switching unit 30, a voltage divider and an emitter stage, in which a resistor R31 and a resistor R32 are connected in parallel, are connected to a power supply terminal V, and a diode D and a capacitor (D) are connected to the base and emitter terminals. C33 is formed of a PNP transistor TR34 connected in parallel, and is switched according to the signal of the first voltage dividing unit 20 to output a predetermined signal.

The second switching unit 40 has a base end connected to the first switching unit 30 through a resistor R41, and a collector end is connected to the power supply terminal V through a pull-up resistor R44. The NpN transistor TR43 is connected to the data receiving end of the control device, and the emitter end is grounded, and the emitter end and the base end are connected via a resistor R42, and the signal of the first switching unit 30 is changed. It is switched to output a predetermined signal accordingly.

The second inverter 50 is connected to the data transmitting end of the electronic control device through the resistor R50, and inverts and outputs the signal output from the data transmitting end of the electronic control device.

The third switching unit 60 has a base end connected to the second inverter 50 through a voltage divider in which the resistor R61 and the resistor R62 are connected in parallel, the emitter stage is grounded, and the collector stage is the first stage. An NPN transistor TR63 is connected to the connection of the voltage divider 20 and the first switching unit 30, and is switched according to the signal of the inverter 50 to output a predetermined signal.

The fourth switching unit 70 has an NPN transistor TR73 having a base end connected to a resistor R71 and connected to a data transmitting end of an electronic controller through a resistor R70, and a base end and a collector end connected to a resistor R72. And switch according to the signal of the data transmitter to output a predetermined signal.

The fifth switching unit 80 has a base end connected to a collector end of the fourth switching unit 70 NPN transistor TR73 through a resistor R81, and an emitter end connected to a front end V. The terminal terminal and the base terminal are formed of a PNP transistor TR83 connected by a resistor R82, and are swung according to the signal of the fourth switching unit 70 to output a predetermined signal.

In the second voltage dividing unit 90, a resistor R91 and a resistor R92 are connected in parallel to each other and connected to the collector terminal of the fifth switching unit 80 and the PNP transistor TR83, and the fifth switching unit 80 is connected. ) The signal potential is divided and output.

One end of the fourth capacitor C100 is grounded to the case, and the other end of the fourth capacitor C100 is connected to the fault signal output terminal to remove various noises introduced from the outside.

The sixth switching unit 110 includes a filter in which a resistor R111 and a capacitor C112 are connected in parallel so that one side of the resistor R111 is connected to the output terminal of the first inverter 2, and the base stage is connected to the filter. An NPN transistor TR114 connected in parallel with R113, an emitter terminal is grounded, and a collector terminal connected to a pull-up resistor R115 connected to one power supply terminal V, and the first inverter 2 Switch according to the signal of) and outputs a predetermined signal accordingly.

The seventh switching unit 120 has a base end connected to the sixth switching unit 110 and the fourth switching unit 70 through a resistor R121, an emitter end is grounded, and a collector end is connected to the first switching unit 70. The NPN transistor TR123 is connected between the voltage dividing resistors R61 and R62 of the third switching unit 60, and the emitter terminal and the base terminal are connected to the resistor R122, and the sixth switching unit 110 includes the NPN transistor TR123. It is switched according to the signal and outputs a predetermined signal accordingly.

Referring to the preferred embodiment according to the present invention configured as described above in detail according to the operation process as follows.

During communication between the fault check device and the electronic control device, when a connector is connected to the check device L line and outputs a "low" signal, the constant voltage section 1 maintains the output signal of the L line at a constant potential and pulls up a resistor ( R1) outputs a "low" signal.

Then, the noise is removed through the second capacitor C2, inverted through the first inverter 2, and a "high" signal is applied to the receiving terminal of the electronic controller through the resistor R2.

Then, the electronic controller performs data transmission and reception with the inspection apparatus through the checker K line through the data receiving end and the data transmitting end by the following operation.

In the case where the check device L line is kept "low" and the check device K line transmits data, when the K line outputs a predetermined signal, that is, for example, outputs a "high" signal, the first voltage divider ( At 20), the potential of the signal is divided and output as a signal of a constant potential by the control diode ZD which is a constant voltage diode.

At this time, the second capacitor C10 removes various noises introduced from the outside.

Then, when the signal of the first voltage dividing unit 20 is applied to the base terminal of the PNP transistor TR34 of the first switching unit 30 through a voltage divider in which the resistor R31 and the resistor R32 are connected in parallel, the first switching is performed. The base end of the PNP transistor TR34 of the unit 30 is switched off while maintaining a high potential.

At the same time, since the NPN transistor TR43 of the second switching unit 40 is also turned off, the second switching unit 40 thrusts a signal of “high” by a pull-up resistor R44 having one end connected to the power supply terminal V. To the data receiver.

In addition, when the K line outputs a "low" signal, a "low" signal is applied to the data receiving end to transmit the data signal.

At the same time, the sixth switching unit 110 removes noise of the “high” signal output from the first inverter 2 from the filter consisting of the resistor R111 and the capacitor C112 and then connects the resistor R113 in parallel. When applied to the base terminal of the NPN transistor TR114 through the NPN transistor TR114 is switched on to output a "low" signal through the pull-up resistor (R115).

Then, since the NPN transistor TR123 of the seventh switching unit 120 maintains the switching off state, the signal of the electronic control device data transmission end is output to the check device K line.

When the data transmitter outputs a signal of "high" through the resistor R50, the second inverter 50 inverts the signal output from the data transmitter and outputs a signal of "low".

Then, since the resistor R61 and the resistor R62 are connected in parallel, the third switching unit 60 switches off the NPN transistor TR63 by the "low" signal of the second inverter 50 applied through the voltage divider. The K line remains "high" because it maintains state.

Unlike the above, when the data transmitter outputs a "low" signal, the NPN transistor TR63 is switched on according to the above operation, and thus the K line maintains a "low" signal.

Therefore, the inspection apparatus K line receives a signal from the data transmission end of the electronic control apparatus by the above operation.

Unlike in the data transmission / reception, when there is no connection of the L line connector of the inspection apparatus, the L line outputs a “high” signal, and the constant voltage unit 1 maintains the output signal of the L line at a constant potential, and the pull-up resistor ( A signal of "high" is output by R1). Then, the high signal is removed through the second capacitor C2, the noise is inverted through the first inverter 2, and applied as a low signal to the receiving terminal of the electronic controller through the resistor R2. do.

At this time, the NPN transistor TR114 of the sixth switching unit 110 is switched off by the "low" signal of the first inverter 2.

Then, a signal of “high” is applied to the base terminal of the seventh switching unit 120 NPN transistor TR123 through the pull-up resistor R115 to be switched on.

As the seventh switching unit 120 is left, a signal transmitted from the electronic control device data transmission terminal to the inspection device K line is blocked, and at the same time, a failure signal is applied only to the failure signal output terminal through the resistor R70, thereby preventing unnecessary signals. Prevent transmission.

When a fault signal is output from the data transmission terminal of the electronic controller, for example, a "high" signal is output, the NPN transistor TR73 of the fourth switching unit 70 is switched on to output a "high" signal.

At the same time, the base terminal of the PNP transistor TR83 of the fifth switching unit 80 has a low potential, and thus is switched on so that the "high" signal is divided into a voltage divider 90 having a resistance R91 and a resistance R92 in parallel. ) To the fault signal output terminal.

In this case, the fourth capacitor C100 removes various noises introduced from the outside.

Even when the data transmitting end outputs a "low" signal, the "low" signal is output to the fault signal output end by the above operation.

As such, the present invention can prevent unnecessary external signals from being transmitted by intermittently intercepting data transmission and failure signal output of the electronic control device data transmission stage by using the signal of the checker L line, thereby eliminating electromagnetic radiation. It is possible to prevent damage to the electronic control unit due to a defect.

Claims (3)

A communication device between a check device and an electronic control device, comprising: constant voltage means connected to the check device L line and maintaining a signal on the L line at a constant potential, pull-up means connected to the constant voltage means to stabilize the signal of the constant voltage means; A first signal inverting means connected to the pull-up means and inverting a signal of the pull-up means to be applied to the receiving end of the electronic control device, one side of which is connected to the check device L line and the K line and the fault signal output terminal, and the other side of the case to ground Filtering means (C1, C10, C100) for removing various noises from the outside; a first voltage dividing means connected to the inspection device K line and dividing a signal of the K line; and a first voltage dividing means connected to the first voltage dividing means. A first switching means switched according to a signal of the first voltage divider, a second switching means connected to the first switching means and switched according to a signal of the first switching means, and Second switching means connected to a data transmission end of the control device and inverting a signal outputted from the data transmission end, third switching means connected to the second signal switching means and switched according to a signal of the second signal switching means; Fourth switching means connected to a data transmitting end of the electronic control apparatus and switched according to a signal of the data transmitting end, fifth switching means connected to the fourth switching means and switched according to a signal of the fourth switching means, and the fifth A sixth switching means connected to the switching means and including a second voltage dividing means for dividing a signal of the fifth switching means, and connected to an output terminal of the first signal inverting means and switched by a signal of the first signal inverting means; And a sixth switching means connected to the sixth switching means, wherein the sixth switching means is switched by a signal. Communication device between gears. The filter of claim 1, wherein the sixth switching means includes a filter in which a resistor R111 and a capacitor C112 are connected in parallel, and one side of the resistor R111 is connected to an output terminal of the first signal inverting means, and a base end of the filter. Is connected in parallel with a resistor R113, the emitter stage is grounded, and the collector stage is composed of an NPN transistor TR114 connected at one end to a pull-up resistor 115 connected to a power supply terminal V. Communication device between the device and the electronic controller. The method according to claim 1, wherein the seventh switching means, the base end is connected to the output terminal of the sixth switching means and the input terminal of the fourth switching means through the resistor (R121), the emitter stage is grounded, the collector stage is the A communication device between the inspection device and the electronic control device, characterized in that the NPN transistor TR123 is connected between the voltage divider resistors R61 and R62 of the third switching means, and the emitter stage and the base stage are connected to the resistor R122. .