KR20210027651A - Guiding device for seat belt - Google Patents

Abstract

The present invention relates to a technology for improving passenger safety by optimizing the route of a seat belt according to a passenger′s physical condition. According to the present invention, provided is a seat belt guide device which is characterized in that a sliding section is provided on an upper portion of a seatback, and a belt guide is moved left and right in the sliding section to change the position of a shoulder belt hung on the belt guide.

Description

Seat belt guide device{GUIDING DEVICE FOR SEAT BELT}

The present invention relates to a seat belt guide device for improving passenger safety by optimizing a route of a seat belt according to a passenger's physical condition.

As a result of the child protection evaluation of seat belts by EuroNCAP, the route of the belt supporting the shoulders escapes to the outside of the child passengers, and there is a problem that the passengers are separated in case of an accident.

In other words, in the case of the existing seat belt, it is suitable for restraining adult passengers, but in the case of child passengers, the route of the shoulder belt supporting the shoulder is located in the outer direction of the vehicle compared to adult passengers, thereby restraining the upper body of the child passenger. There is a difficulty in doing so, and there is a problem in that the field safety performance is deteriorated due to the child passengers moving forward in the event of an accident.

To solve this problem, a method of using a car seat that can be installed by arbitrarily changing the route of the shoulder belt has been proposed, but EuroNCAP does not allow the use of a car seat that changes the route of the shoulder belt after 2020. There is a need for a way to optimize the belt route without changing the belt route.

The matters described as the background art are only for enhancing an understanding of the background of the present invention, and should not be taken as acknowledging that they correspond to the prior art already known to those of ordinary skill in the art.

KR 10-2000-0064583 A

The present invention has been devised to solve the above-described problems, and is to provide a seat belt guide device that improves safety by optimizing the route of a seat belt according to a passenger's physical condition.

The configuration of the present invention for achieving the above object is provided with a sliding section on the top of the seat back; It may be characterized in that the belt guide is moved left and right on the sliding section to change the position of the shoulder belt hung on the belt guide.

An actuator providing an operating force for movement of the belt guide; A load sensor that detects a load of a passenger seated on the seat cushion; It may further include a controller for calculating an output value for the load detected by the load sensor and controlling the operation of the actuator according to the calculated output value.

The controller calculates an output value for moving the belt guide toward the inside of the seatback as the load decreases; As the load increases, an output value for moving the belt guide toward the outside of the seatback may be calculated.

When the load is below the first reference value, an output value is calculated so that the belt guide is located at the innermost side of the seatback in the sliding section; When the load exceeds the second reference value, an output value may be calculated so that the belt guide is located at the outermost side of the seatback in the sliding section.

When the load exceeds the first reference value and is less than or equal to the second reference value, an output value may be calculated so that the belt guide linearly moves according to the load within the sliding section.

An actuator providing an operating force for movement of the belt guide; A height sensor that detects a seated height of a passenger seated on the seat cushion; It may further include a controller that calculates an output value for the seated height detected by the height sensor and controls the operation of the actuator according to the calculated output value.

The controller calculates an output value for moving the belt guide toward the inside of the seatback as the seating key decreases; As the sitting height increases, an output value for moving the belt guide toward the outside of the seatback may be calculated.

When the sitting height is less than or equal to the third reference value, an output value is calculated so that the belt guide is located at the innermost side of the seatback in the sliding section; When the seated height exceeds the fourth reference value, an output value may be calculated such that the belt guide is positioned at the outermost side of the seatback in the sliding section.

When the sitting height exceeds the third reference value and is less than or equal to the fourth reference value, an output value may be calculated so that the belt guide linearly moves according to the load within the sliding section.

A mode switching switch electrically connected to the controller and configured to convert a moving mode of the belt guide into an auto mode or a manual mode; It may further include a movement control switch that is electrically connected to the controller and operates to move the belt guide left and right in the manual mode.

The sliding section may be provided by forming a long sliding hole along the left and right longitudinal direction on one side of the upper end of the seatback.

A sliding plate is installed on one side of the upper end of the seatback; A sliding hole is formed through the seatback and the sliding plate; As the belt guide is inserted into the sliding hole, one end of the belt guide protrudes to the outside of the seatback to catch the shoulder belt, and the other end is located inside the seatback, so that an actuation force can be provided from the actuator.

The belt guide is provided with a fitting portion formed in the middle, penetrating through the sliding hole; At the upper end of the fitting portion, the guide portion is bent toward the other side of the upper end of the seatback, so that a shoulder belt may be hung on the bottom surface of the guide portion.

The present invention through the above-described problem solving means, by moving the belt guide to the left or right of the seat back to change the route of the shoulder belt supporting the passenger, to optimize the route of the belt according to the physical condition of the passenger seated on the seat. do.

Therefore, according to the movement of the belt guide, the upper body of the child passenger is stably supported, and thus, in the event of an accident, the child passenger is prevented from leaving the belt and bounces forward, thereby protecting the child passenger more safely.

1 is a view showing a state in which a seat belt guide device according to the present invention is installed in a seat back.
Figure 2 is a view for explaining the overall configuration and coupling relationship of the seat belt guide device according to the present invention.
3 is a flowchart showing a control process in which the seat belt guide device according to the present invention is operated in an auto mode.
Figure 4 is a view showing a comparison of the operation state of the belt guide in accordance with the present invention moved to the inside and outside of the seatback.

The preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The seat belt guide device of the present invention is applicable to two rows of seats of a vehicle, and the belt guide 10 is configured to be movable along a sliding section.

Referring to Figure 1, looking at the present invention in detail, a sliding section is provided on the upper portion of the seatback (1), the belt guide 10 is moved left and right on the sliding section, the shoulder belt hung on the belt guide 10 The position of (2) changes.

That is, the belt guide 10 is moved to the left or right of the seatback 1 while the shoulder belt 2 is hung on the belt guide 10, so that the shoulder belt 2 hung on the belt guide 10 is Moving together, the position of the shoulder belt (2) changes, and the route of the shoulder belt (2) supporting the passenger is changed, so that the route of the belt is optimized according to the physical condition of the passenger seated in the seat. , It will improve the safety of passengers.

In particular, in the case of a child passenger, the shoulder belt 2 is positioned in the inner direction of the vehicle according to the movement of the belt guide 10, thereby stably supporting the upper body of the child passenger, and thus the child passenger is separated forward in case of an accident. By preventing the accident, it is possible to more safely protect child passengers.

On the other hand, with the configuration of the first embodiment of the present invention, it is possible to control the movement operation of the belt guide 10 to be automatically performed according to the load condition of the passenger seated on the seat. For this purpose, the actuator 30 and the load It may be configured to further include a sensor 40 and a controller (CLR).

1 and 2, a motor actuator 30 is provided to provide an operating force for the movement of the belt guide 10, and a load sensor 40 for detecting the load of a passenger seated on the seat cushion is provided. do.

In addition, when a load detected by the load sensor 40 is input to the controller CLR, an output value for the input load is calculated, and the operation of the actuator 30 is controlled according to the calculated output value.

At this time, the output value may be a value determined by a resistance value that changes according to the load. When the passenger is not seated, the resistance value is detected high, and when the passenger is seated, the resistance value is detected low. When the load is large, the resistance value decreases. Accordingly, the output value for controlling the operation of the actuator 30 varies according to the resistance value.

Preferably, the controller (CLR) calculates an output value for moving the belt guide 10 toward the inside of the seatback 1 as the load decreases, and the belt guide 10 moves the seatback as the load increases. The output value moving toward the outside of (1) is calculated.

For example, when the load is below the first reference value, the output value is calculated so that the belt guide 10 is located at the innermost side of the seatback 1 in the sliding section. That is, as the actuator 30 is operated by the output value and the belt guide 10 is moved, the belt guide 10 is moved to a position corresponding to the innermost side of the seatback 1 as shown on the right side of FIG. 4. .

In addition, when the load exceeds the second reference value, the output value is calculated so that the belt guide 10 is located at the outermost side of the seatback 1 in the sliding section. That is, as the actuator 30 is operated by the output value and the belt guide 10 is moved, the belt guide 10 is moved to a position corresponding to the outermost side of the seatback 1 as shown on the left side of FIG. 4. .

In addition, when the load exceeds the first reference value and is less than or equal to the second reference value, the output value is calculated so that the belt guide 10 linearly moves according to the load within the sliding section. That is, the actuator 30 is operated by the output value and the belt guide 10 is moved, so that the belt guide 10 can be moved in position within the sliding section according to the load.

For example, when the first reference value is 35.5kg, and the second reference value is 50kg, the belt guide 10 is located at the innermost side of the seatback 1 among the sliding sections in a section where the load is 35.5kg or less, and the load is 35.5kg. The belt guide 10 is positioned according to the load in the sliding section in the 2nd section exceeding kg and less than 50kg. Finally, in the 3rd section exceeding 50kg, the belt guide 10 is the most of the seatback 1 among the sliding sections. It will be located on the outside.

On the other hand, with the configuration of the second embodiment of the present invention, it is possible to control the movement operation of the belt guide 10 to be automatically performed according to the seating height condition of the passenger seated on the seat, for this purpose, the actuator 30 and, It may be configured to further include a height sensor 40 and a controller (CLR).

1 and 2, a motor actuator 30 is provided to provide an actuating force for movement of the belt guide 10, and a height sensor 50 for detecting the sitting height of a passenger seated on the seat cushion is provided. It is equipped. For reference, the height sensor 50 is a sensor that detects passengers using ultrasonic waves or the like, and in some cases, it may be controlled to detect the height of the head end of the passenger by replacing the seated key and calculate an output value.

In addition, when the seated key detected by the height sensor 40 is input to the controller CLR, an output value for the input seated key is calculated, and the operation of the actuator 30 is controlled according to the calculated output value.

Preferably, the controller (CLR) calculates an output value for moving the belt guide 10 toward the inside of the seatback 1 as the sitting height decreases, and the belt guide 10 increases as the sitting height increases. The output value is calculated to move toward the outside of the seat back (1).

For example, when the sitting height is less than or equal to the third reference value, the output value is calculated so that the belt guide 10 is located at the innermost side of the seatback 1 in the sliding section. That is, as the actuator 30 is operated by the output value and the belt guide 10 is moved, the belt guide 10 is moved to a position corresponding to the innermost side of the seatback 1 as shown on the right side of FIG. 4. .

In addition, when the sitting height exceeds the fourth reference value, the output value is calculated so that the belt guide 10 is positioned at the outermost side of the seatback 1 in the sliding section. That is, as the actuator 30 is operated by the output value and the belt guide 10 is moved, the belt guide 10 is moved to a position corresponding to the outermost side of the seatback 1 as shown on the left side of FIG. 4. .

In addition, when the seated height exceeds the third reference value and is less than or equal to the fourth reference value, an output value is calculated so that the belt guide 10 linearly moves according to the seated height within a sliding section. That is, the actuator 30 is operated by the output value and the belt guide 10 is moved, so that the belt guide 10 may be moved in position within the sliding section according to the sitting key.

For reference, in the above description, the output value is individually calculated using the load described in the first embodiment and the seated key described in the second embodiment, but the output value can be calculated by considering the load and the sitting height together. In this case, the output value may be calculated according to the relationship between the load and the seated height, or the output value may be determined based on the table value.

For reference, a controller (CLR) according to an exemplary embodiment of the present invention is a nonvolatile memory (not shown) configured to store data relating to an algorithm configured to control the operation of various components of a vehicle or a software instruction to reproduce the algorithm. (Not shown) and data stored in the corresponding memory may be implemented through a processor (not shown) configured to perform an operation described below. Here, the memory and the processor may be implemented as individual chips. Alternatively, the memory and processor may be implemented as a single chip integrated with each other. The processor may take the form of one or more processors.

In addition, referring to Figure 2, in the present invention, the movement of the belt guide 10 can be configured to be actively and automatically controlled through a controller (CLR), and can be configured to be moved by manual manipulation. have.

To this end, in the present invention, the mode change switch 22 is electrically connected to the controller (CLR), and the movement mode of the belt guide 10 is changed to an auto mode or a manual mode by the operation of the mode change switch 22. Can be switched to.

In addition, the movement control switch 23 is electrically connected to the controller CLR, and the belt guide 10 can be moved left and right in the manual mode according to the operation of the movement control switch 23.

That is, in a state in which the auto mode is activated, the belt guide 10 can be automatically moved to the left or right by controlling the operation of the actuator 30 according to the load and/or seating height of the passenger seated on the seat.

In addition, when the mode switching switch 22 is operated from the auto mode to the manual mode and the manual mode is activated, the actuator 30 is operated according to the operation of the movement control switch 23, thereby operating the belt guide 10. It can be moved to the left or right.

For reference, the mode switching switch 22 and the movement control switch 23 may be installed on the seatback 1 adjacent to the belt guide 10, and preferably installed on the sliding plate 20 to be described later. have.

On the other hand, referring to Figures 1 and 2, the sliding section provided to guide the movement of the belt guide 10 of the present invention is a sliding hole 21 of a long hole along the left and right longitudinal direction on one side of the top of the seatback (1). ) Can be provided.

The sliding hole 21 may be implemented by installing a sliding plate 20 at a position of the seat back 1 on which the belt guide 10 is mounted.

Specifically, a sliding plate 20 is installed on one side of an upper end of the seatback 1, and a sliding hole 21 is formed through the seatback 1 and the sliding plate 20.

In addition, as the belt guide 10 is inserted into the sliding hole 21, one end of the belt guide 10 protrudes to the outside of the seatback 1 to catch the shoulder belt 2, and the other end of the seatback 1 It is located inside and receives an operating force from the actuator 30.

That is, the actuator 30 is fixed to the frame of the seatback 1 provided inside the seatback 1, and the other end of the belt guide 10 is connected to the actuator 30. Accordingly, the operating force of the actuator 30 is transmitted to the other end of the belt guide 10 so that the belt guide 10 can be moved left and right along the longitudinal direction of the sliding hole 21.

In addition, the belt guide 10 is formed in the shape of a rod, the fitting portion 11 is formed in the middle, is provided through the sliding hole 21, the upper end of the fitting portion 11 is a seat back (1) ), the guide portion 12 is bent toward the other side of the upper end, so that the shoulder belt 2 is caught on the bottom surface of the guide portion 12.

That is, when the guide portion 12 of the belt guide 10 is formed to protrude to the outside of the seat covering in a'b' shape, when there is no need to hang the shoulder belt 2 on the guide portion 12, for example, a giant body In the case of passengers on board, the shoulder belt 2 can be separated from the guide 12 and used.

For reference, the belt guide 10 of the present invention may be molded of a steel material, and the guide part 12 is configured such that an injection product of a resin material is attached so that the steel frame is not exposed in appearance.

Meanwhile, referring to FIG. 3, a process of operating the seat belt guide device of the present invention in the auto mode will be described, and it is determined whether the current belt guide movement mode is the auto mode through the controller (CLR) (S10).

As a result of the determination, when it is determined in the auto mode, the load and/or the sitting height are detected by the load sensor 40 and/or the height sensor 50 installed on the seat (S20), and the detected load and/or the sitting height are It monitors whether there is a change in the resistance value (S30). On the other hand, if it is not in the auto mode, it enters the manual mode.

In the monitoring process, when a change in the resistance value occurs, an output value for the resistance value is calculated (S40).

Subsequently, the calculated output value is applied to the actuator 30 to control the operation of the actuator 30 (S50).

That is, when a child passenger is on board and detected with a relatively small load and/or sitting height, a relatively high resistance value is detected, and an output value corresponding to the above-described high resistance value is applied to the actuator. Accordingly, as shown on the right side of FIG. 4, the belt guide 10 is moved to the innermost position of the seatback 1 in the sliding section, thereby safely supporting the upper body of the child passenger.

On the other hand, when an adult passenger is on board and a relatively large load and/or sitting height are detected, a relatively low resistance value is detected, and an output value corresponding to the low resistance value is applied to the actuator. Accordingly, as shown on the left side of FIG. 4, the belt guide 10 is moved to a position corresponding to the outermost side of the seatback during the sliding section, thereby stably supporting the upper body of the adult passenger.

On the other hand, the present invention has been described in detail only for the above specific examples, but it is obvious to those skilled in the art that various modifications and modifications are possible within the scope of the technical idea of the present invention, and it is natural that such modifications and modifications belong to the appended claims. .

1: Seat back
2: shoulder belt
10: belt guide
11: fitting
12: guide part
20: sliding plate
21: sliding hole
22: mode change switch
23: movement control switch
30: actuator
40: load sensor
50: height sensor
CLR: Controller

Claims (13)

A sliding section is provided on the top of the seatback;
A seat belt guide device, characterized in that the belt guide is moved left and right on the sliding section to change the position of the shoulder belt hung on the belt guide. The method according to claim 1,
An actuator providing an operating force for movement of the belt guide;
A load sensor that detects a load of a passenger seated on the seat cushion;
And a controller for calculating an output value for the load detected by the load sensor and controlling the operation of the actuator according to the calculated output value. The method according to claim 2,
The controller,
As the load decreases, an output value for moving the belt guide toward the inside of the seatback is calculated;
A seat belt guide device, characterized in that as the load increases, an output value for moving the belt guide toward the outside of the seat back is calculated. The method of claim 3,
When the load is less than or equal to the first reference value, an output value is calculated so that the belt guide is located at the innermost side of the seatback in the sliding section;
When the load exceeds the second reference value, the seat belt guide device, characterized in that the output value is calculated so that the belt guide is located at the outermost side of the seat back in the sliding section. The method of claim 4,
When the load exceeds the first reference value and is less than or equal to the second reference value, an output value is calculated so that the belt guide linearly moves according to the load within a sliding section. The method according to claim 1,
An actuator providing an operating force for movement of the belt guide;
A height sensor that detects a seated height of a passenger seated on the seat cushion;
And a controller for calculating an output value for the seated height detected by the height sensor, and controlling an operation of the actuator according to the calculated output value. The method of claim 6,
The controller,
As the sitting height is smaller, an output value for moving the belt guide toward the inside of the seatback is calculated;
A seat belt guide device, characterized in that, as the sitting height increases, an output value for moving the belt guide toward the outside of the seat back is calculated. The method of claim 7,
When the sitting height is less than or equal to the third reference value, an output value is calculated so that the belt guide is located at the innermost side of the seatback in the sliding section;
When the seated height exceeds the fourth reference value, an output value is calculated such that the belt guide is positioned at the outermost side of the seat back in the sliding section. The method of claim 8,
When the sitting height exceeds the third reference value and is less than or equal to the fourth reference value, an output value is calculated so that the belt guide moves linearly according to the load within a sliding section. The method according to claim 2,
A mode switching switch electrically connected to the controller and configured to convert a moving mode of the belt guide into an auto mode or a manual mode;
And a movement control switch electrically connected to the controller and configured to move the belt guide left and right in the manual mode. The method according to claim 1,
The sliding section is a seat belt guide device, characterized in that provided by forming a long sliding hole along the left and right longitudinal direction on one side of the upper end of the seat back. The method of claim 11,
A sliding plate is installed on one side of the upper end of the seatback;
A sliding hole is formed through the seatback and the sliding plate;
A seat belt guide device, characterized in that as the belt guide is inserted into the sliding hole, one end of the belt guide protrudes to the outside of the seatback to catch the shoulder belt, and the other end is located inside the seatback to receive an actuation force from the actuator. The method of claim 11,
The belt guide,
The fitting portion is formed in the middle, and is provided through the sliding hole;
A seat belt guide device, characterized in that the guide portion is bent toward the other side of the upper end of the seatback at the upper end of the fitting portion, and a shoulder belt is caught on the bottom surface of the guide portion.

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