KR102145185B1 - Trouble diagnosing apparatus of inside mirror - Google Patents

Abstract

The present invention discloses an inside mirror fault diagnosis apparatus. The device for diagnosing a failure of an inside mirror according to the present invention is a control module in which a failure occurs when an overvoltage higher than the driving voltage is applied to the reflectance adjusting member (eg, EC electrolytic layer) by the control module responsible for varying the driving voltage. In spite of the presence of, overvoltage supplied to the EC (Electronic Chromic) electrolytic layer can be effectively blocked.

Description

Fault diagnosis device of inside mirror {TROUBLE DIAGNOSING APPARATUS OF INSIDE MIRROR}

The present invention relates to an apparatus for diagnosing a failure of an inside mirror, and more particularly, to an apparatus for diagnosing a failure of an inside mirror to prevent an overvoltage greater than a driving voltage from being applied to a reflectance adjusting member (eg, an EC electrolytic layer).

In general, the inside mirror is a device that automatically detects light from a rear vehicle through an illuminance sensor and lowers the reflectance of the glass to eliminate the driver's glare.

In addition, the inside mirror is also referred to as a photosensitive mirror. Since it is mainly used for room mirrors, it is commonly used as a'ECM (Electronic Chromic Mirror) room mirror'.

When driving at night, if the headlights of the rear vehicle are too bright or the light is pointing upwards, the driver is blinded by the light from the rear vehicle reflected in the rearview mirror and cannot drive properly. In this case, a device that removes glare Is the inside mirror.

When the inside mirror is not in operation, the amount of light reflected by the room mirror is large, causing a severe glare, but when the inside mirror is operated, the amount of light is significantly reduced, so that the glare is hardly felt.

In addition, the illuminance sensor of the inside mirror is usually installed in the center above the rearview mirror and serves to detect the illuminance of the halo shining from the rear of the vehicle.

Thereafter, the control module of the inside mirror determines the amount of light transmitted from the rear based on the output signal of the illuminance sensor, and according to the determination result, the power supply to the EC (Electronic Chromic) electrolytic layer is turned on or off, or the EC (Electronic Chromic) Controls the power supplied to the electrolytic layer.

The EC (Electronic Chromic) electrolytic layer responding to this causes coloration or discoloration to control the amount of light transmitted from the rear so that the driver does not feel glare.

In this case, when the voltage supplied to the EC (Electronic Chromic) electrolytic layer is applied as an overvoltage, it is difficult to normally use the inside mirror due to damage to the EC (Electronic Chromic) electrolytic layer.

In addition, if the reason that the voltage supplied to the EC (Electronic Chromic) electrolytic layer is overvoltage is due to an abnormality occurring in the control module of the inside mirror, the overvoltage supplied to the EC (Electronic Chromic) electrolytic layer is blocked by the control module in which the failure occurs. There is a limit to doing it.

Republic of Korea Patent Publication No. 10-2011-0045725 (2011.05.04)

Accordingly, the present invention was created to solve the above problems, and an object of the present invention is to apply an overvoltage higher than the driving voltage to the reflectance adjusting member (eg, EC electrolytic layer) to the control module responsible for varying the driving voltage. In the case of this, the object is to provide an apparatus for diagnosing a failure of an inside mirror for efficiently blocking overvoltage supplied to an electronic chromic (EC) electrolytic layer despite the presence of a control module in which a failure has occurred.

The object of the present invention is not limited to the above-mentioned object, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, a fault diagnosis apparatus for an inside mirror according to a first aspect of the present invention generates an output voltage based on a control module for varying a driving voltage of a reflectance adjusting member, and a control voltage for varying the driving voltage. And a driving circuit unit for providing the output voltage to the reflectance adjusting member and a comparison circuit unit for generating a comparison result voltage by comparing the driving voltage and the output voltage, and providing the comparison result voltage to the control module, the The control module provides a switch-on control signal for controlling the driving circuit part to be turned on or a switch-off control signal for controlling the driving circuit part to be turned off according to the comparison result voltage to the driving circuit part.

In addition, a fault diagnosis apparatus of an inside mirror according to a second aspect of the present invention for achieving the above object includes a control module for varying a driving voltage of a reflectance adjusting member, and an output voltage based on a control voltage for varying the driving voltage. A switch-on control signal for generating and providing the output voltage to the reflectance adjusting member, and a switch-on control signal for controlling the driving circuit unit to be turned on according to a result of comparing the driving voltage and the output voltage or the driving circuit unit And a comparison circuit unit providing a switch-off control signal for controlling the state to the driving circuit unit.

Therefore, in the present invention, when an overvoltage higher than the driving voltage is applied to the reflectance adjusting member (eg, the EC electrolytic layer), the control module responsible for varying the driving voltage causes the EC (Electronic Chromic) There is an advantage of being able to efficiently block overvoltage supplied to the electrolytic layer.

The effects of the present invention are not limited to the effects mentioned above, and other effects that are not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a diagram showing a fault diagnosis apparatus for an inside mirror according to a first embodiment of the present invention.
2 is a diagram illustrating an operation process of the fault diagnosis apparatus shown in FIG. 1.
3 is a diagram illustrating an apparatus for diagnosing a failure of an inside mirror according to a second embodiment of the present invention.
In addition, FIG. 4 is a diagram illustrating an operation process of the fault diagnosis apparatus shown in FIG. 3.

Advantages and features of the present invention, and a method of achieving them will become apparent with reference to the embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various forms different from each other, and only these embodiments make the disclosure of the present invention complete, and common knowledge in the technical field to which the present invention pertains. It is provided to fully inform the scope of the invention to those who have it, and the invention is only defined by the scope of the claims.

The same reference numerals refer to the same elements throughout the specification. "And/or" includes each and every combination of one or more of the recited items.

Although the first, second, etc. are used to describe various elements, components, and/or sections, it should be understood that these elements, components and/or sections are not limited by these terms. These terms are only used to distinguish one element, component or section from another element, component or section. Therefore, it goes without saying that the first element, the first element, or the first section mentioned below may be a second element, a second element, or a second section within the technical idea of the present invention.

The terms used in the present specification are for describing exemplary embodiments and are not intended to limit the present invention. In this specification, the singular form also includes the plural form unless otherwise specified in the phrase. As used in the specification, "comprises" and/or "comprising" refers to the presence of one or more other components, steps, actions and/or elements, and/or elements, steps, actions and/or elements mentioned. Or does not exclude additions.

Unless otherwise defined, all terms (including technical and scientific terms) used in the present specification may be used with meanings that can be commonly understood by those of ordinary skill in the art to which the present invention belongs. In addition, terms defined in commonly used dictionaries are not interpreted ideally or excessively unless explicitly specifically defined.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram showing a fault diagnosis apparatus 100 for an inside mirror according to a first embodiment of the present invention.

Referring to FIG. 1, an apparatus for diagnosing a failure of an inside mirror relates to an apparatus for diagnosing a failure of an inside mirror to prevent an overvoltage greater than a driving voltage from being applied to a reflectance adjusting member (eg, an EC electrolytic layer 200).

That is, the device for diagnosing a failure of the inside mirror may include the control module 120, the driving circuit unit 130, and the comparison circuit unit 140.

The control module 120 serves to vary the driving voltage of the reflectance adjusting member (eg, the EC electrolytic layer 200).

For example, when the control module 120 receives an illuminance sensor signal corresponding to the illuminance from the illuminance sensor, the control module 120 is for varying the driving voltage of the reflectance adjusting member (eg, EC electrolytic layer, 200) based on the received illuminance sensor signal. Determine the voltage level. Thereafter, the control module 120 generates a control voltage using the determined voltage level and the current driving voltage, and provides the generated control voltage to the driving circuit unit 130.

Here, the illuminance sensor is for detecting illuminance. For example, the illuminance sensor may detect illuminance of a halo illuminated from the rear of the vehicle. Hereinafter, as an example, the illuminance sensor detects the illuminance of the halo illuminated from the rear, and will be described in detail.

The driving circuit unit 130 receives a control voltage from the control module 120 and generates an output voltage for providing to a reflectance adjusting member (eg, an EC electrolytic layer 200) based on the received control voltage. The driving circuit unit 130 supplies the generated output voltage to a reflectance adjusting member (eg, an EC electrolytic layer 200).

In this case, when the control voltage provided from the control module 120 is the same as the driving voltage of the current reflectance adjusting member (eg, EC electrolytic layer, 200), the driving circuit unit 130 includes a reflectance adjusting member (eg, EC electrolytic layer, 200). By maintaining the output voltage supplied to the device as it is, the driving voltage of the current reflectance adjusting member (eg, EC electrolytic layer, 200) is maintained.

On the other hand, when the control voltage provided from the control module 120 is different from the driving voltage of the current reflectance adjusting member (for example, the EC electrolytic layer 200), the driving circuit unit 130 has a reflectance adjusting member ( Example: An output voltage for providing to the EC electrolytic layer, 200 is generated, and the generated output voltage is used as a new driving voltage of the reflectance adjusting member (eg, EC electrolytic layer, 200). 200).

The comparison circuit unit 140 receives the driving voltage of the reflectance adjusting member (eg, EC electrolytic layer, 200) and the output voltage of the driving circuit unit 130, compares the supplied driving voltage and the output voltage, and controls the comparison result. A circuit configuration provided to the module 120 is provided.

The comparison circuit unit 140 compares the driving voltage of the reflectance adjusting member (eg, the EC electrolytic layer 200) with the output voltage of the driving circuit unit 130 and provides the comparison result to the control module 120 as a comparison result voltage. It is possible to do.

For example, when the driving voltage of the reflectance adjusting member (eg, the EC electrolytic layer 200) is equal to or greater than the output voltage of the driving circuit unit 130, the comparison circuit unit 140 generates a low signal to generate the comparison result voltage to the control module 120 ) Can be provided.

As a response of the control module 120 to this, the control module 120 generates a switch-on control signal and provides the generated switch-on control signal to the driving circuit unit 130 when the comparison result voltage, which is a low signal, is provided.

The driving circuit unit 130 operates normally according to a switch-on control signal provided from the control module 120. Here, the normal operation of the driving circuit unit 130 refers to generating an output voltage for providing to the reflectance adjusting member (eg, EC electrolytic layer, 200) based on the control voltage of the control module 120, and the generated output Refers to a state in which voltage is supplied to a reflectance control member (eg, EC electrolytic layer, 200).

On the other hand, when the driving voltage of the reflectance adjusting member (eg, the EC electrolytic layer 200) is less than the output voltage of the driving circuit unit 130, the comparison circuit unit 140 generates a high signal as a result of the comparison and generates the control module 120 Can be provided.

As a response of the control module 120 to this, the control module 120 generates a switch-off control signal and provides the generated switch-off control signal to the driving circuit unit 130 when the comparison result voltage, which is a high signal, is provided.

The driving circuit unit 130 blocks generation of an output voltage to be provided to the reflectance adjusting member (eg, the EC electrolytic layer 200) according to the switch-off control signal provided from the control module 120.

That is, the comparison circuit unit 140 includes an output voltage supplied from the driving circuit unit 130 as a driving voltage of the reflectance adjusting member (eg, EC electrolytic layer, 200) and a driving voltage of the reflectance adjusting member (eg, EC electrolytic layer, 200). Is provided, and a source for determining whether the driving voltage of the reflectance adjusting member (eg, the EC electrolytic layer 200) is overvoltage is provided as the result is generated as a voltage as a result of comparison after performing comparison. .

Finally, the control module 120 receives the comparison result voltage from the comparison circuit unit 140, performs a determination on the received comparison result voltage, and controls the driving circuit unit 130 to be turned on according to the determination result. An ON control signal is generated and provided to the driving circuit unit 130 or a switch-off control signal for controlling the driving circuit unit 130 to an off state is generated and provided to the driving circuit unit 130.

Here, when the comparison circuit unit 140 outputs the comparison result as the driving voltage of the reflectance adjusting member (eg, the EC electrolytic layer 200) and the output voltage of the driving circuit unit 130 are different, the output voltage of the driving circuit unit 130 It can be predicted that an abnormality has occurred in any one of the control module 120 and the driving circuit unit 130 involved in the process of generating.

At this time, the present invention focuses on a case in which an abnormality occurs in the control module 120.

That is, due to the occurrence of an abnormality in the control module 120, the driving voltage of the reflectance adjusting member (eg, the EC electrolytic layer 200) and the output voltage of the driving circuit unit 130 may be different.

Accordingly, as described above, the control module 120 in which the abnormality is generated receives the comparison result voltage from the comparison circuit unit 140, and generates a switch-on control signal or a switch-off control signal based on this, and the driving circuit unit 130 It is not desirable to provide it.

Accordingly, the control module 120 controls the switch-on based on the first control module for varying the driving voltage of the reflectance adjusting member (eg, the EC electrolytic layer 200) and the comparison result voltage provided from the comparison circuit unit 140 It is preferable that a signal or a switch-off control signal is generated and provided separately as a second control module for providing to the driving circuit unit 130.

That is, it is preferable that the first control module and the second control module are provided as independent modules and do not affect each other.

Accordingly, a port (A) in which the first control module is connected to the driving circuit unit 130 and a port (B) in which the second control module is connected to the driving circuit unit 130 are also independently provided.

In addition, the fault diagnosis apparatus of the inside mirror changes the input voltage for operation of the control module 120 to the voltage standard of the control module 120 or changes the driving voltage of the reflectance control member (eg, EC electrolytic layer, 200). It is also possible to further include a regulator 110 for changing the voltage standard of the comparison circuit unit 140.

2 is a diagram illustrating an operation process of the fault diagnosis apparatus shown in FIG. 1.

Referring to FIG. 2, the fault diagnosis apparatus compares the driving voltage of the reflectance adjusting member (eg, the EC electrolytic layer 200) with the output voltage of the driving circuit unit 130 through the comparison circuit unit 140 (S100 ).

Thereafter, when the driving voltage of the reflectance adjusting member (eg, EC electrolytic layer, 200) in the comparison circuit unit 140 is equal to or greater than the output voltage of the driving circuit unit 130 (S102), the comparison result voltage is generated as a low signal and the generated comparison The resulting voltage is provided to the control module 120 (S104).

Thereafter, the control module 120 operates normally to provide a control voltage for varying the driving voltage of the reflectance adjusting member (eg, the EC electrolytic layer 200) to the driving circuit unit 130, as well as the driving circuit unit 130 After generating a switch-on control signal for normal operation, the generated switch-on control signal is provided to the driving circuit unit 130 (S106).

Thereafter, the driving circuit unit 130 operates normally according to the switch-on control signal provided from the control module 120, and through this, based on the control voltage provided from the control module 120, a reflectance adjusting member (eg, an EC electrolytic layer) , 200), and provides the generated output voltage to the reflectance adjusting member (eg, EC electrolytic layer, 200) as a driving voltage of the reflectance adjusting member (eg, EC electrolytic layer, 200) ( S110).

On the other hand, when the driving voltage of the reflectance control member (eg, EC electrolytic layer, 200) in the comparison circuit unit 140 is less than the output voltage of the driving circuit unit 130 in step S102, the comparison result voltage is generated as a high signal and the generated comparison The resulting voltage is provided to the control module 120 (S104-1).

Thereafter, the control module 120 determines that an abnormality has occurred in the supply of the driving voltage of the reflectance adjusting member (eg, the EC electrolytic layer 200), and accordingly transmits a switch-off control signal for blocking the operation of the driving circuit unit 130. And provides the generated switch-off control signal to the driving circuit unit 130 (S106-1).

Thereafter, the driving circuit unit 130 becomes in an inoperable state according to the switch-off control signal provided from the control module 120 (S108-1).

Accordingly, the output voltage supplied from the driving circuit unit 130 to the reflectance adjusting member (eg, the EC electrolytic layer 200) is also cut off (S110-1).

In addition, when the fault diagnosis of the inside mirror is finished, the process for executing the above-described steps is also finished (S112).

3 is a diagram illustrating an apparatus 200 for diagnosing a failure of an inside mirror according to a second embodiment of the present invention.

Referring to FIG. 3, the device 200 for diagnosing a failure of an inside mirror is based on a control module 320 for varying a driving voltage of a reflectance adjusting member (eg, an EC electrolytic layer 200), and a control voltage for varying the driving voltage. A driving circuit unit 330 that generates an output voltage and provides the generated output voltage to a reflectance control member (eg, EC electrolytic layer, 200), and a driving voltage and drive of the reflectance control member (eg, EC electrolytic layer, 200) According to a result of comparing the output voltage of the circuit unit 330, a switch-on control signal for controlling the driving circuit unit 330 to be turned on or a switch-off control signal for controlling the driving circuit unit 330 to be turned off is transmitted to the driving circuit unit 330 It may also be provided in a configuration including a comparison circuit unit 340 provided to.

In other words, it is a method in which the comparison circuit unit 340 is provided as an independent structure, not a structure that interlocks with the control module 320.

The comparison circuit unit 340 receives the driving voltage of the reflectance adjusting member (eg, the EC electrolytic layer 200) and the output voltage of the driving circuit unit 330, compares the supplied driving voltage and the output voltage, and compares the result according to the comparison result. A switch-on control signal for controlling the driving circuit unit 330 to be turned on is generated, and the generated switch-on control signal is directly provided to the driving circuit unit 330.

For example, the comparison circuit unit 340 is a switch for instructing the normal operation of the driving circuit unit 330 when the driving voltage of the reflectance adjusting member (eg, the EC electrolytic layer 200) is equal to or greater than the output voltage of the driving circuit unit 330 An ON control signal is generated, and the generated switch-on control signal is provided to the driving circuit unit 330.

As a response of the driving circuit unit 330 to this, the driving circuit unit 330 performs a normal operation by preferentially responding to the switch-on control signal provided from the comparison circuit unit 340, and is provided from the control module 320 in this normal operation state. An output voltage for supply to the reflectance control member (eg, EC electrolytic layer, 200) is generated based on the controlled voltage.

On the other hand, when the driving voltage of the reflectance adjusting member (eg, the EC electrolytic layer 200) is less than the output voltage of the driving circuit unit 330, the comparison circuit unit 340 controls the switch-off to block the operation of the driving circuit unit 330 A signal is generated and the generated switch-off control signal is provided to the driving circuit unit 330.

As a response of the driving circuit unit 330 to this, the driving circuit unit 330 preferentially responds to the switch-off control signal provided from the comparison circuit unit 340 to supply voltage to the reflectance adjusting member (eg, EC electrolytic layer, 200). Cut off the circuit driving for

In addition, the fault diagnosis apparatus 200 of the inside mirror changes the input voltage for the operation of the control module 320 to the voltage standard of the control module 320, or the reflectance control member (eg, EC electrolytic layer, 200) It is also possible to further include a regulator 310 for changing the driving voltage to the voltage standard of the comparison circuit unit 340.

In addition, FIG. 4 is a diagram illustrating an operation process of the fault diagnosis apparatus 200 shown in FIG. 3.

Referring to FIG. 4, the fault diagnosis apparatus 200 compares the driving voltage of the reflectance adjusting member (eg, the EC electrolytic layer 200) and the output voltage of the driving circuit unit 330 through the comparison circuit unit 340 (S200). .

Thereafter, when the driving voltage of the reflectance adjusting member (eg, the EC electrolytic layer 200) in the comparison circuit unit 340 is equal to or greater than the output voltage of the driving circuit unit 330 (S202), the driving circuit unit 330 is A switch-on control signal is generated, and the generated switch-on control signal is provided to the driving circuit unit 330 (S204).

Thereafter, the driving circuit unit 330 performs a normal operation in response to the switch-on control signal provided from the comparison circuit unit 340 preferentially, and in this normal operation state, the reflectance adjusting member based on the control voltage provided from the control module 320 (Example: EC electrolytic layer, 200) to generate an output voltage for supply (S206).

Thereafter, the driving circuit unit 330 supplies the output voltage generated in step S206 to the reflectance adjusting member (eg, the EC electrolytic layer 200) (S208 and S210).

On the other hand, when the driving voltage of the reflectance control member (eg, the EC electrolytic layer 200) in the comparison circuit unit 340 is less than the output voltage of the driving circuit unit 330 in step S202, a switch for blocking the operation of the driving circuit unit 330 An off control signal is generated, and the generated switch off control signal is provided to the driving circuit unit 330 (S204-1).

Thereafter, the driving circuit unit 330 preferentially responds to the switch-off control signal provided from the comparison circuit unit 340 to block the driving of the circuit for supplying voltage to the reflectance adjusting member (eg, the EC electrolytic layer 200) (S206- One).

As the circuit operation of the driving circuit unit 330 is blocked in step S206-1, the voltage provided from the driving circuit unit 330 to the reflectance adjusting member (eg, the EC electrolytic layer 200) is also cut off (S208-1).

In addition, when the fault diagnosis of the inside mirror is finished, the process for executing the above-described steps is also finished (S212).

Although the embodiments of the present invention have been described with reference to the above and the accompanying drawings, those of ordinary skill in the art to which the present invention pertains can implement the present invention in other specific forms without changing the technical spirit or essential features. You can understand that there is. Therefore, it should be understood that the embodiments described above are illustrative and non-limiting in all respects.

In addition, since the present invention is to prevent an overvoltage higher than the driving voltage from being applied to the reflectance adjusting member (e.g., EC electrolytic layer), the possibility of commercialization or business is sufficient as well as a degree that can be practically clearly implemented. It is a possible invention.

100, 300: inside mirror fault diagnosis device
110, 310: regulator 120, 320: control module
130, 330: driving circuit unit 140, 340: comparison circuit unit
200: reflectance adjusting member

Claims (6)

In the inside mirror fault diagnosis apparatus,
A control module for varying the driving voltage of the reflectance adjusting member;
A driving circuit unit generating an output voltage based on a control voltage for varying the driving voltage and providing the output voltage to the reflectance adjusting member; And
Comprising a comparison circuit unit for comparing the driving voltage and the output voltage to generate a comparison result voltage, and providing the comparison result voltage to the control module,
The control module provides a switch-on control signal for controlling the driving circuit unit in an on state or a switch-off control signal for controlling the driving circuit unit in an off state according to the comparison result voltage to the driving circuit unit,
When the switch-off control signal is provided to the driving circuit, the generation of the output voltage is blocked. The method of claim 1,
The inside mirror fault diagnosis device,
A regulator for changing an input voltage for operation of the control module to a voltage standard of the control module or a regulator for changing the driving voltage to a voltage standard of the comparison circuit unit; further comprising, a fault diagnosis apparatus of an inside mirror. The method according to claim 1 or 2,
The comparison circuit unit generates the comparison result voltage as a low signal when the driving voltage is greater than or equal to the output voltage,
The control module is an inside mirror fault diagnosis device that generates the switch-on control signal when the low signal is applied. The method according to claim 1 or 2,
The comparison circuit unit generates the comparison result voltage as a high signal when the driving voltage is less than the output voltage,
When the high signal is applied, the control module generates the switch-off control signal. In the inside mirror fault diagnosis apparatus,
A control module for varying the driving voltage of the reflectance adjusting member;
A driving circuit unit generating an output voltage based on a control voltage for varying the driving voltage and providing the output voltage to the reflectance adjusting member; And
A comparison circuit unit providing a switch-on control signal for controlling the driving circuit unit to an on state or a switch-off control signal for controlling the driving circuit unit to an off state according to a result of comparing the driving voltage and the output voltage to the driving circuit unit; Including,
When the switch-off control signal is provided to the driving circuit, the generation of the output voltage is blocked. The method of claim 5,
The inside mirror fault diagnosis device,
A regulator for changing an input voltage for operation of the control module to a voltage standard of the control module or a regulator for changing the driving voltage to a voltage standard of the comparison circuit unit; further comprising, a fault diagnosis apparatus of an inside mirror.

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