DE102009047938A1 - Motor controller for controlling electric sun visor arrangement that covers windscreen of automobile, has processing unit for operating signal producing unit to produce deceleration signal to control motor speed during pulling of visor body - Google Patents

Abstract

The controller (3) has a processing unit (33) for determining whether a functional signal produced by an evaluation unit (31) matches with a functional message. The processing unit operates a signal producing unit (34) for rotating a motor (101) in a direction based on a function assigned to actual actuation of manually actuated switches (102, 103) when the signal does not match with the message. The processing unit operates the signal producing unit for producing a deceleration signal for progressive controlling of rotational speed of the motor during a last stage of pulling of a visor body.

Description

This invention relates to a motor controller, more particularly to a motor controller for a sun visor assembly.

An electric sun visor assembly is generally used to cover a windshield of an automobile. The conventional electric sun visor assembly includes a base, a flexible screen body, and a bezel provided at a free end of the flexible screen body.

The aforementioned conventional electric sun visor assembly is disadvantageous in that, when the flexible shield body is retracted, a considerable noise is generated due to a collision between the diaphragm and the base because the flexible shield body is retracted at a relatively high speed as shown in FIG 3 is shown. In addition, the conventional electric sun visor assembly is designed for use in a tropical or subtropical zone. As such, when the conventional electric sun visor assembly is used in cool zones, it is possible for the conventional electric sun visor assembly to be abnormally effective or ineffective.

Therefore, the main object of the present invention is to provide a motor controller for a sun visor assembly which can overcome the aforementioned disadvantages of the prior art.

It is the object of the present invention to provide a motor controller with improved characteristics.

This object is achieved by a motor control according to claim 1.

According to the present invention, a motor controller for a sun visor assembly comprises a judging unit, a recording unit, a signal generating unit, and a processing unit. The sun visor assembly includes a flexible shield body, a mechanism effective to extend or retract the flexible shield body, a motor for controlling the mechanism, a first manually operated switch associated with a function to extend the flexible shield body, and a second manually operated switch associated with a function to retract the flexible screen body. The judging unit is adapted to be coupled to the first and second manually operated switches, and is operative to determine a currently operated one of the first and second manually operated switches and to generate a function signal indicative of the function. which is assigned to the currently actuated one of the first and second manually operated switches, which is determined by the same. The recording unit is coupled to the judging unit and stores in the same a functional message indicating the function assigned to a previously operated one of the first and second manually operated switches. The signal generation unit is adapted to be coupled to the engine and is operative to control a direction of rotation and rotational speed of the motor. The processing unit is coupled to the judging unit, the recording unit, and the signal generating unit, and is operative to determine whether the function signal generated by the judging unit agrees with the function message stored in the recording unit. When it is determined that the function signal does not coincide with the function message, the processing unit operates the signal generation unit to rotate the motor in one direction based on the function assigned to the currently operated one of the first and second manually operated switches. The processing unit further operates the signal generating unit to generate a deceleration signal for progressively reducing the rotational speed of the motor during a final phase of retraction of the flexible screen body.

Other features and advantages of the present invention will become apparent in the following detailed description of the preferred embodiment with reference to the accompanying drawings.

Preferred embodiments of the present invention will be explained in more detail below with reference to the accompanying drawings. Show it:

1 a circuit block diagram of the preferred embodiment of a motor controller according to this invention;

2A to 2C Flow diagrams of the preferred embodiment of a method according to this invention, using the in 1 shown motor control to be implemented; and

3 FIG. 4 is a diagram illustrating noise generated during a retraction of a conventional electric sun visor assembly and a sun visor assembly incorporating the principles of the present invention 1 shown used motor control.

With reference to 1 It is shown that the preferred embodiment of a motor control 3 according to the present invention, a judging unit 31 , a recording unit 32 , a signal generation unit 34 and a processing unit 33 includes.

The engine control 3 This invention is attached to a sun visor assembly.

The sun visor assembly is installed in an automobile (not shown) and includes a flexible shield body (not shown), a mechanism (not shown) operative to extend or retract the flexible shield body, a bezel (not shown) attached to a vehicle free end of the flexible screen body is provided, a motor 101 , which drives an operation of the mechanism, a first manually operated switch 102 to which a function is assigned to extend a flexible screen body, and which, when pressed by a user (not shown), is actuated, a second manually operated switch 103 to which a function is assigned to retract a flexible screen body, and which, when pressed by the user (not shown), is actuated, an automatically operated switch 104 to which a function is assigned to retract the flexible screen body and which is actuated when a transmission of the automobile is shifted into reverse, and a power supply 100 that with the engine control 3 connected is.

The assessment unit 31 is with the first and second manually operated switches 102 . 103 and the automatically operated switch 104 and operative to activate a currently actuated one of the first and second manually operated switches 102 . 103 and the automatically operated switch 104 and to generate a function signal indicative of the function corresponding to the currently operated one of the first and second manually operated switches 102 . 103 and the automatically operated switch 104 indicates.

The recording unit 32 is with the appraisal unit 31 connected and stores in the same a functional message that the function of a previously operated of the first and the second manually operated switch 102 . 103 and the automatically operated switch 104 indicates.

The signal generation unit 34 is with the engine 101 connected and is effective to one direction of rotation and a rotational speed of the motor 101 in a manner to be described hereinafter.

The processing unit 33 is with the appraisal unit 31 , the recording unit 32 and the signal generation unit 34 is connected and is effective to determine whether the function signal, by the assessment unit 31 is generated in accordance with the functional message that is in the recording unit 32 is stored. When it is determined that the function signal does not match the function message, the processing unit operates 33 the signal generation unit 34 to the engine 101 in one direction, based on the function of the currently operated one of the first and second manually operated switches 102 . 103 and the automatically operated switch 104 is assigned. In this embodiment, the processing unit operates 33 the signal generation unit 34 to an acceleration signal to progressively increase the rotational speed of the motor 101 , z. From zero to a predetermined value during an initial stage of extending / retracting the flexible screen body. In addition, in this embodiment, the processing unit operates 33 the signal generation unit 34 to provide a deceleration signal for progressively reducing the rotational speed of the motor 101 , z. From the predetermined value back to zero during an output stage of the extension / retraction of the flexible screen body. Further, in this embodiment, the processing unit operates 33 the signal generation unit 34 to provide, during an intermediate stage between the initial stage and the final stage of the extension / retraction of the flexible screen body, a constant signal for constantly maintaining the rotational speed of the motor 101 , z. At the predetermined value.

It should be noted that the signal generation unit 34 is formed by a plurality of metal oxide semiconductor field effect transistors (MOSFETs, metal oxide semiconductor field effect transistors). The rotational speed of the motor 101 is by varying a load cycle of the signal generation unit 34 controlled, thereby an effective operating current for driving the motor 101 adjust.

The engine control 3 further comprises a current detector 35 and a temperature sensor 36 , The current detector 35 is with the signal generation unit 34 and the processing unit 33 connected and is effective to an output current of the signal generating unit 34 and to generate an output signal indicative of the output current detected thereby.

The processing unit 33 is also operative to determine if the output signal produced by the current detector 35 is generated exceeds a threshold. If it is determined that the output signal through the current detector 35 is generated exceeds the threshold holds the processing unit 33 an operation of the signal generation unit 34 and the engine control 3 on, which prevents the engine 101 and the engine control 3 to be damaged.

The temperature sensor 36 is with the processing unit 33 and is operative to sense the ambient temperature and to produce an output indicative of the ambient temperature sensed thereby.

The processing unit 33 is also effective to an operating current of the engine control 3 and the threshold based on the output signal provided by the temperature sensor 36 is generated, set. Such a structure provides normal operation of the engine controller 3 safe at different ambient temperatures.

The preferred embodiment of a method using the aforementioned engine control 3 will be implemented according to this invention will now be with further reference to 2A to 2C described.

At one step 1 represents the processing unit 33 the operating current of the engine control 3 and the threshold based on the output signal provided by the temperature sensor 36 is produced.

At one step 2 occurs the processing unit 33 in a sleep mode or sleep mode (sleep mode).

At one step 3 determines the assessment unit 31 whether the first manually operated switch 102 is pressed.

At one step 4 the process goes to a step 5 over, if at the step 3 it is determined that the first manually operated switch 102 is pressed. Otherwise, the process goes to a step 10 above.

At the step 5 generates the assessment unit 31 a function signal indicating the function corresponding to the first manually operated switch 102 is assigned.

It should be noted that the function signal generated at this step is the processing unit 33 awakens from sleep mode.

At one step 6 determines the processing unit 33 whether the function signal at the step 5 is generated in accordance with the functional message that is in the recording unit 32 is stored.

At one step 7 the process goes to a step 8th over, if at the step 6 determining that the function signal does not match the functional message, indicating that the flexible screen body is in a retracted state. Otherwise, that is, the function signal coincides with the functional message, indicating that the flexible screen body is in an extended state, the flow goes back to the step 2 ,

At the step 8th operates the processing unit 33 the signal generation unit 34 to the engine 101 to rotate in a forward direction to thereby extend the flexible screen body.

At one step 9 operates the processing unit 33 the signal generation unit 34 to generate the acceleration signal, the constant signal, and the deceleration signal during the first twenty-five percent, the next fifty percent, and the last twenty five percent of the duration of the flexible shield body run, respectively. Thereafter, the process is ended.

At the step 10 determines the assessment unit 31 whether the second manually operated switch 103 is pressed.

At one step 11 the process goes to a step 12 over, if at the step 10 it is determined that the second manually operated switch 103 is pressed. Otherwise, the process goes to a step 17 above.

At the step 12 generates the assessment unit 31 a function signal indicating the function of the second manually operated switch 103 is assigned.

It should be noted that the function signal generated at this step is the processing unit 33 awakens from sleep mode.

At one step 13 determines the processing unit 33 whether the function signal at the step 12 has been generated in accordance with the functional message contained in the recording unit 32 is stored.

At one step 14 the process goes to a step 13 over, if at the step 13 determining that the function signal does not match the functional message, indicating that the flexible screen body is in an extended state. Otherwise, ie, the function signal coincides with the functional message, indicating that the flexible screen body is in the retracted state, the flow goes back to the step 2 ,

At one step 15 operates the processing unit 33 the signal generation unit 34 to the engine 101 to rotate in a reverse direction, thereby retracting the flexible screen body.

At one step 16 operates the processing unit 33 the signal generation unit 34 to generate the acceleration signal, the constant signal, and the deceleration signal during the first twenty-five percent, the next fifty percent, and the last twenty-five percent of the duration of the flex screen retraction, respectively. Thereafter, the process is ended.

At the step 17 determines the assessment unit 31 whether the automatically operated switch 104 is pressed.

At one step 18 the process goes to a step 19 about when the assessment unit 31 determines that the automatically operated switch 104 is pressed. Otherwise, the process goes back to the step 2 ,

At the step 19 generates the assessment unit 31 a function signal indicating the function that the automatically operated switch 104 is assigned.

It should be noted that the function signal generated at this step is the processing unit 33 awakens from sleep mode.

At one step 20 determines the processing unit 33 whether the function signal at the step 19 has been generated in accordance with the functional message contained in the recording unit 32 is stored.

At one step 21 the process goes to a step 22 over, if at the step 20 determining that the function signal does not match the functional message, indicating that the flexible screen body is in an extended state. Otherwise, ie, the function signal coincides with the functional message, indicating that the flexible screen body is in the retracted state, the flow goes back to the step 2 ,

At the step 22 operates the processing unit 33 the signal generation unit 34 to the engine 101 to rotate in the reverse direction, thereby retracting the flexible screen body.

At one step 23 operates the processing unit 33 the signal generation unit 34 to generate the acceleration signal, the constant signal, and the deceleration signal during the first twenty-five percent, the next fifty percent, and the last twenty-five percent of the duration of the flex screen retraction, respectively. Thereafter, the process is ended.

From the above description, when the mechanism is operated to retract the flexible screen body, since the engine control 3 the present invention, the rotational speed of the motor 101 is progressively reduced during the last stage of retraction of the flexible screen body, noise due to collisions between the shutter, the mechanism and other components such as a base, the sun visor assembly is significantly suppressed, as in 3 is shown.

Claims (13)

Motor control ( 3 ) for a sun visor assembly, the sun visor assembly comprising a flexible shield body, a mechanism operative to extend or retract the flexible shield body, an engine ( 101 ) for controlling the mechanism, a first manually operated switch ( 102 ), which is assigned a function to extend the flexible screen body, and a second manually operated switch (FIG. 103 ) to which a function is assigned to retract the flexible screen body, wherein the engine control ( 3 ) comprises: a judgment unit ( 31 ) adapted to operate with the first and second manually operated switches ( 102 . 103 ) and operable to operate a currently actuated one of the first and second manually operated switches ( 102 . 103 ) and to generate a function signal indicating the function corresponding to the currently operated one of the first and second manually operated switches ( 102 . 103 ) determined by the same; a recording unit ( 32 ) associated with the assessment unit ( 31 ) and stores therein a functional message indicative of the function associated with a previously actuated one of the first and second manually operated switches ( 102 . 103 ) is assigned; a signal generation unit ( 43 ), which is adapted to work with the engine ( 101 ) and is operative to control a rotational direction and rotational speed of the motor ( 101 ) to control; and a processing unit ( 33 ) associated with the assessment unit ( 31 ), the recording unit ( 32 ) and the signal generation unit ( 34 ) and is operative to determine whether the function signal generated by the judging unit ( 31 ) generated is consistent with the functional message that is in the recording unit ( 32 ), wherein if it is determined that the function signal does not match the functional message, the processing unit ( 33 ) the signal generation unit ( 34 ) operates the engine ( 101 ) in one direction based on the function corresponding to the currently operated one of the first and second manually operated switches ( 102 . 103 ), and wherein the processing unit ( 33 ) the signal generating unit ( 34 ) to provide a deceleration signal for progressively reducing the rotational speed of the motor ( 101 ) during a final stage of retraction of the flexible screen body. Motor control ( 3 ) according to claim 1, wherein the processing unit ( 33 ) the signal generation unit ( 34 ) to generate the deceleration signal during the last twenty-five percent of the duration of the retraction of the flexible screen body. Motor control ( 3 ) according to one of claims 1 or 2, in which the processing unit ( 33 ) the signal generating unit ( 34 ) to provide an acceleration signal for progressively increasing the rotational speed of the engine ( 101 ) during an initial stage of retraction of the flexible screen body. Motor control ( 3 ) according to claim 3, wherein the processing unit ( 33 ) the signal generation unit ( 34 ) to generate the acceleration signal during the first twenty-five percent of the duration of the flexible screen body retraction. Motor control ( 3 ) according to one of claims 3 or 4, in which the processing unit ( 33 ) the signal generating unit ( 34 ) to provide a constant signal for maintaining the rotational speed of the motor ( 101 ) during an intermediate stage between the initial stage and the final stage of the retraction of the flexible screen body. Motor control ( 3 ) according to one of claims 1 to 5, in which the processing unit ( 33 ) the signal generating unit ( 34 ) to generate the deceleration signal during a final stage of deployment of the flexible screen body. Motor control ( 3 ) according to claim 6, wherein the processing unit ( 33 ) the signal generation unit ( 34 ) to generate the deceleration signal during the last twenty-five percent of the duration of deployment of the flexible screen body. Motor control ( 3 ) according to claim 6 or 7, wherein the processing unit ( 33 ) the signal generating unit ( 34 ) to provide an acceleration signal for progressively increasing the rotational speed of the engine ( 101 ) during an initial stage of extension of the flexible screen body. Motor control ( 3 ) according to claim 8, wherein the processing unit ( 33 ) the signal generation unit ( 34 ) to generate the acceleration signal during the first twenty-five percent of the duration of deployment of the flexible screen body. Motor control ( 3 ) according to claim 8 or 9, wherein the processing unit ( 33 ) the signal generation unit ( 34 ) is operated to provide a constant signal for maintaining the rotational speed of the motor ( 101 ) during an intermediate stage between the initial stage and the final stage of extension of the flexible screen body. Motor control ( 3 ) according to one of claims 1 to 10, in which the assessment unit ( 31 ) is further adapted to operate with an automatically operated switch ( 104 ) of the sun visor assembly, which is assigned a function to retract the flexible screen body, the judging unit (12) 31 ) is operative to activate a currently actuated one of the first and second manually operated switches ( 102 . 103 ) and the automatically operated switch ( 104 ), the function signal generated by the assessment unit ( 31 ) indicating the function corresponding to the currently operated one of the first and second manually operated switches ( 102 . 103 ) and the automatically operated switch ( 104 ) assigned by the assessment unit ( 31 ), wherein the functional message contained in the recording unit ( 32 ) indicating a function of a previously actuated one of the first and second manually operated switches ( 102 . 103 ) and the automatically operated switch ( 104 ). Motor control ( 3 ) according to one of claims 1 to 11, in which the processing unit ( 33 ) an operation of the signal generation unit ( 34 ) stops when an output current of the signal generation unit ( 34 ) exceeds a threshold. Motor control ( 3 ) according to claim 12, further comprising a temperature sensor ( 36 ) connected to the processing unit ( 33 ) and is operable to detect the ambient temperature and to produce an output signal indicative of the ambient temperature detected thereby, the processing unit (12) 33 ) an operating current of the engine control ( 3 ) and the Threshold based on the output signal produced by the temperature sensor ( 36 ) is produced.

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