CN113119699A - Sun shield system of automobile skylight and control method of sun shield of automobile skylight - Google Patents

Abstract

The invention discloses a sun shield system of an automobile skylight and a control method of the sun shield of the automobile skylight, wherein the sun shield system comprises a sun shield, a slide rail, a motor and a transmission part, the slide rail is arranged on the automobile skylight, the motor drives the sun shield to slide along the slide rail through the transmission part, the sun shield is driven to slide towards an opening direction when the motor runs in the positive direction, and the sun shield is driven to slide towards a closing direction when the motor runs in the reverse direction; the sun-shading device is characterized by further comprising a first controller and a light sensor used for sensing the sunlight intensity, wherein the first controller is in communication connection with the skylight glass position sensor, the light sensor and the motor so as to control the motor to run forwards or reversely according to sensing information of the skylight glass position sensor and the light sensor. The control method automatically controls the sun shield to be opened or closed according to the current position of the skylight glass and the current sunlight intensity. The sun shield system and the control method realize automatic opening and closing of the sun shield, and can improve user experience and riding feeling.

Description

Sun shield system of automobile skylight and control method of sun shield of automobile skylight

Technical Field

The invention relates to the technical field of automobiles, in particular to a sun shield system of an automobile skylight and a control method of the sun shield of the automobile skylight

Background

In order to improve the ride experience, more and more automobiles are provided with skylight on the automobile ceiling. Generally, a sun visor is disposed inside the sunroof glass.

Currently, a sun visor of an automobile sunroof is manually opened and closed by a user. The manual switch sun visor has the following problems: the operation is laborious and inconvenient; once a user forgets to close the sun visor when locking the vehicle, the sun visor is kept open until the next use of the vehicle, which may cause the cabin to be exposed to sunlight and the temperature to be high.

The above technical problems affect the user experience and riding experience, and therefore, it is necessary to solve the above technical problems.

Disclosure of Invention

In order to solve the technical problems, the invention provides a sun visor system of an automobile skylight, which comprises a sun visor, a slide rail, a motor and a transmission part, wherein the slide rail is arranged on an automobile roof; the sun-shading device is characterized by further comprising a first controller and a light sensor used for sensing the sunlight intensity, wherein the first controller is in communication connection with the skylight glass position sensor, the light sensor and the motor so as to automatically control the motor to run forwards or reversely according to sensing information of the skylight glass position sensor and the light sensor.

This sunshading board system makes first controller operate or the reverse operation according to skylight glass position sensor and optical sensor's response information automatic control motor forward through setting up optical sensor and first controller, has realized opening and close the sunshading board according to the sunshine intensity automatic opening and closing of difference, like this, compares manual opening and close the sunshading board more convenient, intelligent, therefore can promote user experience.

Optionally, the first controller comprises:

the first information acquisition module is in communication connection with the skylight glass position sensor and the optical sensor so as to acquire the current position and the current sunlight intensity of the skylight glass;

the first judgment module is in communication connection with the first information acquisition module so as to judge whether the skylight glass is opened or closed and whether the current sunlight intensity is equal to or greater than a preset sunlight intensity upper limit value;

the first instruction module is in communication connection with the first judgment module and the motor, and is used for sending a reverse operation instruction to the motor when the skylight glass is closed and the current sunlight intensity is equal to or greater than the sunlight intensity upper limit value and sending a forward operation instruction to the motor when the skylight glass is opened.

Optionally, the sun visor has a photovoltaic power generation function, and is connected with a charging port of an on-vehicle storage battery through an electric switch; the sun shield system further comprises a second controller and an electric quantity sensor used for sensing the electric quantity of the sun shield, and the second controller is in communication connection with the electric quantity sensor and the electric switch so as to automatically control the electric switch to be opened and closed according to the sensing information of the electric quantity sensor.

Optionally, the second controller comprises:

the second information acquisition module is in communication connection with the electric quantity sensor so as to acquire the current electric quantity of the sun shield;

the second judgment module is in communication connection with the second information acquisition module so as to judge whether the current electric quantity of the sun shield is greater than a preset electric quantity lower limit value or not;

and the second instruction module is in communication connection with the second judgment module and the electric switch, so that a closing instruction is sent to the electric switch when the current electric quantity of the sun shield is greater than the electric quantity lower limit value, and an opening instruction is sent to the electric switch when the current electric quantity of the sun shield is less than or equal to the electric quantity lower limit value.

Optionally, the sun visor system further comprises a manual switch for a user to manually close the sun visor when the skylight glass is closed and the current sunlight intensity is less than the sunlight intensity upper limit value.

In addition, the invention also provides a control method of the automobile skylight sun shield, which automatically controls the sun shield to be opened or closed according to the current position of the skylight glass and the current sunlight intensity.

According to the control method, the sun shield is automatically opened and closed according to different sunlight intensities, so that the sun shield is more convenient and intelligent to open and close manually, and the user experience can be improved.

Optionally, the automatically controlling the sun visor to open or close according to the current position of the skylight glass and the current sunlight intensity includes:

acquiring the current position and the current sunlight intensity of skylight glass;

judging whether the opening and closing of the skylight glass and the current sunlight intensity are equal to or greater than a preset sunlight intensity upper limit value or not;

when the skylight glass is closed and the current sunlight intensity is equal to or greater than the sunlight intensity upper limit value, the sun shield is automatically controlled to be closed, and when the skylight glass is opened, the sun shield is automatically controlled to be opened.

Optionally, the sun visor has a photovoltaic power generation function, and the sun visor is automatically controlled to start or stop supplying power to a vehicle-mounted storage battery according to the current electric quantity of the sun visor.

Optionally, the automatically controlling the sun visor to start or stop supplying power to an on-vehicle battery according to the current electric quantity of the sun visor includes:

acquiring the current electric quantity of the sun shield;

judging whether the current electric quantity of the sun shield is larger than a preset electric quantity lower limit value or not;

when the current electric quantity of the sun shield is larger than the electric quantity lower limit value, the sun shield is automatically controlled to start to supplement power to a vehicle-mounted storage battery, and when the current electric quantity of the sun shield is smaller than or equal to the electric quantity lower limit value, the sun shield is automatically controlled to stop supplementing power to the vehicle-mounted storage battery.

Optionally, the sun visor is manually closed when the skylight glass is closed and the current sunlight intensity is less than the sunlight intensity upper limit value.

Drawings

FIG. 1 is a schematic view of one embodiment of a sun visor system for a sunroof according to the present invention;

fig. 2 is a logic block diagram of a specific embodiment of the control method for the sun visor of the automobile sunroof provided by the invention.

The reference numerals are explained below:

the vehicle-mounted storage battery comprises a sun shield 1, a slide rail 2, a motor 3, an optical sensor 4, a first controller 5, a second controller 6, an electric switch 7, an electric quantity sensor 8, a manual switch 9, a fuse box 10 and a vehicle-mounted storage battery 11.

Detailed Description

In order to make those skilled in the art better understand the technical solution of the present invention, the technical solution of the present invention is further described in detail below with reference to the accompanying drawings and the detailed description.

As shown in fig. 1, the sun visor system for a vehicle includes a sun visor 1, a slide rail 2, a motor 3, and a transmission member (not visible).

The slide rail 2 is mounted on a vehicle ceiling, and may be specifically embedded between an inner panel and an outer panel of the vehicle ceiling. In the figure, two slide rails 2 are provided, and the two slide rails 2 are respectively arranged on two sides of the sun visor 1, and in practical implementation, the number of the slide rails 2 is not limited to two. The extending direction of the slide rail 2 is not limited herein, and may extend in the vehicle longitudinal direction, may extend in the vehicle width direction, or may extend in an oblique direction inclined with respect to the vehicle longitudinal direction and the vehicle width direction.

The sun visor 1 has a slide cooperating with the slide rail 2 so as to slide along the slide rail 2. The motor 3 runs by means of electric power, and an output shaft of the motor 3 is in transmission connection with the sun shield 1 through a transmission part so as to drive the sun shield 1 to slide along the slide rail 2. When the motor 3 is operated in the forward direction (i.e. the output shaft of the motor 3 is rotated in the forward direction), the sun visor 1 is driven to slide in the opening direction, and when the motor 3 is operated in the reverse direction (i.e. the output shaft of the motor 3 is rotated in the reverse direction), the sun visor 1 is driven to slide in the closing direction.

Specifically, the transmission component may be a screw nut assembly, the screw is connected to the output shaft of the motor 3, and the nut is connected to the sun visor 1, so as to convert the rotation motion of the output shaft into the linear motion of the sun visor 1.

As shown in fig. 1, the sun visor system further comprises a first controller 5 and a light sensor 4. The light sensor 4 is used for sensing the sunlight intensity. The sunroof has a sunroof glass position sensor (not shown) for sensing the position of the sunroof glass. The first controller 5 is in communication connection with the skylight glass position sensor, the optical sensor 4 and the motor 3, and the first controller 5 automatically controls the motor 3 to run forwards or reversely according to the sensing information of the skylight glass position sensor and the sensing information of the optical sensor 4.

Specifically, the first controller 5 includes a first information obtaining module, a first judging module and a first instruction module. The first information acquisition module is in communication connection with the skylight glass position sensor and the light sensor 4 to acquire the current position and the current sunlight intensity of the skylight glass. The first judgment module is in communication connection with the first information acquisition module to judge whether the skylight glass is opened or closed and whether the current sunlight intensity is equal to or greater than a preset sunlight intensity upper limit value. First instruction module and first judging module and motor 3 communication connection to when skylight glass closed and present sunshine intensity equals or is greater than sunshine intensity upper limit value, send reverse operation instruction to motor 3, make motor 3 drive sunshading board 1 and close, when skylight glass opened, send forward operation instruction to motor 3, make motor 3 drive sunshading board 1 and open.

In detail, an opening position corresponding to when the skylight glass is opened and a closing position corresponding to when the skylight glass is closed may be prestored in the first controller 5, and the opening and closing of the skylight glass may be determined by comparing the current position of the skylight glass with the opening position and the closing position. If the current position of the skylight glass is consistent with the opening position, the skylight glass is opened, and if the current position of the skylight glass is consistent with the closing position, the skylight glass is closed.

As above, this sunshading board system makes first controller 5 according to skylight glass position sensor and optical sensor 4's response information control motor 3 forward direction operation or reverse operation through setting up optical sensor 4 and first controller 5, has realized opening and close sunshading board 1 according to the sunshine intensity automatic according to the difference, and like this, it is more convenient, intelligent to compare manual opening and close sunshading board 1, therefore can promote user experience.

Especially, still predetermine sunshine intensity upper limit value in first controller 5, when present sunshine intensity equals or is greater than sunshine intensity upper limit value, make motor 3 drive sunshading board 1 and close, when present sunshine intensity is less than sunshine intensity upper limit value, make motor 3 drive sunshading board 1 and open, like this, even if the user forgets to close sunshading board 1 when locking the vehicle, sunshading board 1 also can be closed automatically when sunshine intensity is stronger to can prevent that the cabin from being exposed to the sun and the temperature is very high, therefore can promote the user and take the impression.

It should be noted that the upper limit value of the sunlight intensity is pre-stored in the first controller 5, and in actual implementation, the upper limit value of the sunlight intensity may be preset by a manufacturer, or may be set by a user through an input port.

It should be noted that the communication connection described herein may be any connection capable of implementing data transmission, such as a wired connection or a wireless connection.

In the illustrated embodiment, the first controller 5 is connected to the optical sensor 4 and the motor 3 by wires, and in detail, the first controller 5 is connected between the optical sensor 4 and the motor 3 by a wire. The optical sensor 4 is also connected to the vehicle-mounted battery 11 by a wire, so that the wire performs both a data transmission function and a power transmission function, that is, the first controller 5, the optical sensor 4, and the motor 3 are supplied with power from the vehicle-mounted battery 11.

Specifically, a sensing period may be set for the light sensor 4, so that the light sensor 4 uses an average value of the sunlight intensity in one sensing period as the current sunlight intensity, and sends the current sunlight intensity to the first controller 5 once in each sensing period. For example, when the sensing period is set to 30 minutes, the light sensor 4 calculates the current sunlight intensity by dividing the sum of the sunlight intensities for 30 minutes by 30, and transmits the calculated current sunlight intensity to the first controller 5, and since the current sunlight intensity is calculated every 30 minutes, the current sunlight intensity is transmitted every 30 minutes to the first controller 5. Thus, the problem that the sun shield 1 is frequently and automatically opened and closed due to large change of the sunlight intensity in a short time can be avoided.

Specifically, a sunshade plate position sensor can be further arranged to sense the position of the sunshade plate 1, the first controller 5 can control the motor 3 to start and stop according to the position of the sunshade plate, and the specific configuration is as follows: the motor 3 is controlled to be stopped when the sun visor 1 is opened to the fully opened position, or the motor 3 is controlled to be stopped when the sun visor 1 is closed to the fully closed position, or the motor 3 is controlled to be stopped when the sun visor 1 is opened or closed to a preset position between the fully opened position and the fully closed position. In detail, the motor 3 can be controlled to start and stop by controlling the power switch of the motor 3, when the power switch of the motor 3 is switched off, the motor 3 is powered on, so that the motor is started, and when the power switch of the motor 3 is switched on, the motor 3 is powered off, so that the motor is stopped.

Further, as shown in fig. 1, the sun visor 1 has a photovoltaic power generation function, and may be implemented by using a photovoltaic power generation panel as the sun visor 1, or by laying a photovoltaic power generation panel on an outer surface of a body of the sun visor 1. The sun visor 1 and a charging port of the vehicle-mounted battery 11 are connected to the electric switch 7 through a charging wire.

Meanwhile, as shown in fig. 1, the sun visor system further includes a second controller 6 and an electric quantity sensor 8 for sensing the electric quantity of the sun visor 1, and in the illustrated embodiment, the electric switch 7, the electric quantity sensor 8 and the second controller 6 are integrated.

The second controller 6 is in communication connection with the electric quantity sensor 8 and the electric switch 7 so as to automatically control the electric switch 7 to be opened and closed according to the sensing information of the electric quantity sensor 8. When the electric switch 7 is turned on, the charging wire is not conducted; when the electric switch 7 is closed, the charging wire is conducted, and when the charging wire is conducted, the sun shield 1 transmits electricity to the vehicle-mounted storage battery 11 for storage. By the arrangement, abundant solar energy can be utilized to supplement electricity for the vehicle-mounted storage battery 11, and the running cost of the automobile is saved.

Specifically, the second controller 6 includes a second information obtaining module, a second determining module, and a second instruction module. The second information acquisition module is in communication connection with the electric quantity sensor 8 to acquire the current electric quantity of the sun visor 1. The second judging module is in communication connection with the second information obtaining module to judge whether the current electric quantity of the sun visor 1 is larger than a preset electric quantity lower limit value. The second instruction module is in communication connection with the second judgment module and the electric switch 7, so that when the current electric quantity of the sun shield 1 is larger than the electric quantity lower limit value, a closing instruction is sent to the electric switch 7, the sun shield 1 is enabled to convey electricity to the vehicle-mounted storage battery 11 for storage, and when the current electric quantity of the sun shield 1 is smaller than or equal to the electric quantity lower limit value, an opening instruction is sent to the electric switch 7, and the sun shield 1 is enabled to stop transmitting electricity to the vehicle-mounted storage battery 11. So set up, can guarantee that sunshading board 1's electric quantity continues to deposit and transmit electricity to on-vehicle battery 11 again when reaching a certain amount, can avoid frequently charging the harmful effects in the on-vehicle battery 11 life-span like this, and can avoid when sunshading board 1 electric quantity is less, on-vehicle battery 11's electric reflux to sunshading board 1's problem.

It should be noted that the lower limit of the electric quantity is pre-stored in the second controller 6, and in actual implementation, the lower limit of the electric quantity may be preset by a manufacturer, or may be set by a user through an input port.

Further, as shown in fig. 1, the sun visor system further comprises a manual switch 9, the manual switch 9 is connected between the motor 3 and the vehicle-mounted storage battery 11 through a lead, when the manual switch 9 is closed, the motor 3 is powered on to start, the manual switch 9 is opened, and the motor 3 is powered off to stop. Through setting up manual switch 9, when skylight glass closed and present sunshine intensity was less than sunshine intensity upper limit value, the user can close sunshading board 1 by oneself through operation manual switch 9. In the figure, a fuse box 10 is also provided to prevent short-circuiting.

As shown in fig. 2, the control method of the sun visor for the automobile sunroof automatically controls the sun visor 1 to open or close according to the current position of the sunroof glass and the current sunlight intensity.

Specifically, the automatically controlling the sun visor 1 to open or close according to the current position of the skylight glass and the current sunlight intensity includes:

acquiring the current position and the current sunlight intensity of skylight glass;

judging whether the opening and closing of the skylight glass and the current sunlight intensity are equal to or greater than a preset sunlight intensity upper limit value or not;

when the skylight glass is closed and the current sunlight intensity is equal to or greater than the sunlight intensity upper limit value, the sun shield 1 is automatically controlled to be closed, and when the skylight glass is opened, the sun shield 1 is automatically controlled to be opened.

Further, the sun visor 1 has a photovoltaic power generation function, and at this time, as shown in fig. 2, the sun visor 1 is automatically controlled to start or stop supplying power to the vehicle-mounted storage battery according to the current electric quantity of the sun visor 1.

Specifically, according to the present electric quantity control sunshading board 1 of sunshading board 1 and begin or suspend to the on-vehicle battery moisturizing electricity, include:

acquiring the current electric quantity of the sun shield 1;

judging whether the current electric quantity of the sun shield 1 is larger than a preset electric quantity lower limit value or not;

when the current electric quantity of the sun shield 1 is larger than the electric quantity lower limit value, the sun shield 1 is automatically controlled to start to supplement the electricity to the vehicle-mounted storage battery, and when the current electric quantity of the sun shield 1 is smaller than or equal to the electric quantity lower limit value, the sun shield 1 is automatically controlled to stop supplementing the electricity to the vehicle-mounted storage battery.

In addition, as shown in fig. 2, when the sunroof glass is closed and the current sunlight intensity is less than the sunlight intensity upper limit value, the sun visor 1 is manually closed.

The sun visor system of an automobile skylight and the control method of the sun visor of the automobile skylight provided by the invention are described in detail above. The principles and embodiments of the present invention are explained herein using specific examples, which are presented only to assist in understanding the method and its core concepts. It should be noted that, for those skilled in the art, it is possible to make various improvements and modifications to the present invention without departing from the principle of the present invention, and those improvements and modifications also fall within the scope of the claims of the present invention.

Claims (10)

1. The sun visor system of the automobile skylight is characterized by comprising a sun visor, a slide rail, a motor and a transmission part, wherein the slide rail is arranged on an automobile roof, the motor drives the sun visor to slide along the slide rail through the transmission part, the sun visor is driven to slide towards an opening direction when the motor runs in the positive direction, and the sun visor is driven to slide towards a closing direction when the motor runs in the reverse direction; the sun-shading device is characterized by further comprising a first controller and a light sensor used for sensing the sunlight intensity, wherein the first controller is in communication connection with the skylight glass position sensor, the light sensor and the motor so as to automatically control the motor to run forwards or reversely according to sensing information of the skylight glass position sensor and the light sensor.

2. The visor system of claim 1, wherein the first controller comprises:

the first information acquisition module is in communication connection with the skylight glass position sensor and the optical sensor so as to acquire the current position and the current sunlight intensity of the skylight glass;

the first judgment module is in communication connection with the first information acquisition module so as to judge whether the skylight glass is opened or closed and whether the current sunlight intensity is equal to or greater than a preset sunlight intensity upper limit value;

the first instruction module is in communication connection with the first judgment module and the motor, and is used for sending a reverse operation instruction to the motor when the skylight glass is closed and the current sunlight intensity is equal to or greater than the sunlight intensity upper limit value and sending a forward operation instruction to the motor when the skylight glass is opened.

3. The sun visor system of claim 1 wherein the sun visor has a photovoltaic power generation function, the sun visor being connected to a charging port of an on-vehicle battery through an electric switch; the sun shield system further comprises a second controller and an electric quantity sensor used for sensing the electric quantity of the sun shield, and the second controller is in communication connection with the electric quantity sensor and the electric switch so as to automatically control the electric switch to be opened and closed according to the sensing information of the electric quantity sensor.

4. The visor system of claim 3, wherein the second controller comprises:

the second information acquisition module is in communication connection with the electric quantity sensor so as to acquire the current electric quantity of the sun shield;

the second judgment module is in communication connection with the second information acquisition module so as to judge whether the current electric quantity of the sun shield is greater than a preset electric quantity lower limit value or not;

and the second instruction module is in communication connection with the second judgment module and the electric switch, so that a closing instruction is sent to the electric switch when the current electric quantity of the sun shield is greater than the electric quantity lower limit value, and an opening instruction is sent to the electric switch when the current electric quantity of the sun shield is less than or equal to the electric quantity lower limit value.

5. A sun visor system according to any one of claims 1-4, further comprising a manual switch for a user to manually close the sun visor when the roof glass is closed and the current sun intensity is less than the upper limit value of sun intensity.

6. A control method for a sun visor of an automobile skylight is characterized in that the sun visor is automatically controlled to be opened or closed according to the current position of skylight glass and the current sunlight intensity.

7. The control method according to claim 6, wherein the automatically controlling the sun visor to be opened or closed according to the current position of the sunroof glass and the current intensity of sunlight comprises:

acquiring the current position and the current sunlight intensity of skylight glass;

judging whether the opening and closing of the skylight glass and the current sunlight intensity are equal to or greater than a preset sunlight intensity upper limit value or not;

when the skylight glass is closed and the current sunlight intensity is equal to or greater than the sunlight intensity upper limit value, the sun shield is automatically controlled to be closed, and when the skylight glass is opened, the sun shield is automatically controlled to be opened.

8. The control method according to claim 6, characterized in that the sun visor has a photovoltaic power generation function, and the sun visor is automatically controlled to start or stop supplying power to an on-board storage battery according to the current power of the sun visor.

9. The control method according to claim 8, wherein the controlling the sun visor to start or suspend recharging to an on-board battery according to the current charge of the sun visor comprises:

acquiring the current electric quantity of the sun shield;

judging whether the current electric quantity of the sun shield is larger than a preset electric quantity lower limit value or not;

when the current electric quantity of the sun shield is larger than the electric quantity lower limit value, the sun shield is automatically controlled to start to supplement power to a vehicle-mounted storage battery, and when the current electric quantity of the sun shield is smaller than or equal to the electric quantity lower limit value, the sun shield is automatically controlled to stop supplementing power to the vehicle-mounted storage battery.

10. The control method according to any one of claims 1 to 9, wherein the sun visor is manually closed when the sun roof is closed and the current sunlight intensity is less than the sunlight intensity upper limit value.

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