KR20200036486A - Leveling apparatus of blade active control - Google Patents

Abstract

The present invention relates to a blade active-control leveling device. According to one embodiment of the present invention, the blade active-control leveling device includes: a body having a set volume; a driving member provided in the lower part of both sides of the body and provided to be driven on the ground; a blade having a set width and a set height and connected to the front end of the body; a driving unit providing power for adjusting the position of the blade; a position sensor located on the blade to provide position information of a spot installed on the blade; a driving speed sensor located on the body or the driving member to sense rpm of the driving member; and a controller enabling the height of the blade to be adjusted by controlling the driving unit based on the information provided by the driving speed sensor and the position sensor. Therefore, the blade active-control leveling device can adjust the posture of the blade by considering the inclination of the body.

Description

Leveling apparatus of blade active control

The present invention relates to a blade active control leveling device, and more particularly to a blade active control leveling device that can effectively control the attitude of the blade.

At the construction site, work is performed to make the ground suitable for construction before starting construction or during construction. Leveling devices such as bulldozers, wheel loaders, etc. are used to make the ground state as desired.

As the leveling device travels on the ground, the state of the blade positioned in front of the leveling device is adjusted, and the blade performs work in a form that makes the ground set. Since the operation result of the leveling device varies depending on the operation state of the blade, the blade must be effectively operated to obtain a desired result. Accordingly, a skilled worker leveling device is usually operated.

The present invention is to provide a blade active control leveling device that can effectively control the attitude of the blade.

In addition, the present invention is to provide a blade active control leveling device capable of adjusting the height of the blade according to the load.

In addition, the present invention is to provide a blade active control leveling device that can effectively adjust the height of the blade through the information provided by the position sensor and the driving speed sensor.

In addition, the present invention is to provide a blade active control leveling device capable of adjusting the height of both sides of the blade through a position sensor provided on both sides of the blade.

In addition, the present invention is to provide a blade active control leveling device capable of adjusting the height of both sides of the blade and the degree to which the blade is rolled through a blade attitude sensor positioned on the blade.

In addition, the present invention is to provide a blade active control leveling device that can adjust the attitude of the blade in consideration of the degree of inclination of the body through the body attitude sensor provided to the body.

According to an aspect of the invention, the main body having a set volume; A traveling member provided on both lower portions of the main body and provided to be movable with respect to the ground; A blade having a set width and a set height and connected to the front end of the body; A drive unit that provides power to adjust the position of the blade; A position sensor located on the blade to provide position information of a point installed on the blade; A driving speed sensor positioned on the main body or the traveling member and sensing a rotational speed of the traveling member; And a controller that controls the drive unit such that the height of the blade is adjusted through information provided by the position sensor and the drive speed sensor.

In addition, the driving member may be provided as a caterpillar having a plurality of shoe plates around the outside.

In addition, the driving speed sensor includes a housing; A first sensing unit connected to the housing to protrude toward the shoe plate; And a second sensing unit connected to the housing to protrude toward the shoe plate.

In addition, the first sensing unit and the second sensing unit may be provided to be spaced apart by a set distance along a direction in which the shoe plate is moved.

In addition, the first detection unit and the second detection unit may be provided as a proximity sensor that detects when the shoe plate is positioned within a set distance.

In addition, the controller calculates the load applied to the blade through the movement speed calculated through the position information provided by the position sensor and the rotational speed of the driving member provided by the driving speed sensor, and according to the size of the load The height of the blade can be adjusted.

In addition, the controller may control the driving unit such that the height of the blade is raised when the load exceeds a preset reference load.

In addition, the controller may control the driving unit so that the height of the blade is lowered when the load amount is smaller than a preset reference load amount.

In addition, the position sensor, the first position sensor located in the left area of the blade; And a second position sensor located in the right area of the blade, the drive speed sensor comprising: a first drive speed sensor located in the left area; And a second driving sensor positioned in the right area.

In addition, the controller adjusts the height of the left area of the blade through information provided by the first position sensor and the first drive speed sensor, and receives information provided by the second position sensor and the second drive sensor. Through this, the height of the right area of the blade can be adjusted.

In addition, the controller may perform the steps of calculating the load while the work is being performed and adjusting the height of the blade in a closed loop structure.

In addition, the driving speed sensor may be provided detachably.

According to an embodiment of the present invention, a blade active control leveling device capable of effectively controlling the posture of a blade may be provided.

In addition, according to an embodiment of the present invention, a blade active control leveling device capable of adjusting the height of the blade according to the load amount may be provided.

In addition, according to an embodiment of the present invention, a blade active control leveling device capable of effectively adjusting the height of the blade may be provided through information provided by the position sensor and the driving speed sensor.

In addition, according to an embodiment of the present invention, a blade active control leveling device in which the heights on both sides of the blades can be respectively adjusted through a position sensor provided on both sides of the blade may be provided.

In addition, according to an embodiment of the present invention, a blade active control leveling device capable of adjusting the height of both sides of the blade and the degree to which the blade is rolled can be provided through a blade attitude sensor located on the blade.

In addition, according to an embodiment of the present invention, a blade active control leveling device capable of adjusting the attitude of the blade may be provided in consideration of the degree of inclination of the body through the body attitude sensor provided to the body.

1 is a view showing a blade active control leveling device according to an embodiment of the present invention.
FIG. 2 is a view showing the front region of the blade active control leveling device of FIG. 1.
FIG. 3 is a block diagram showing a control relationship of the blade active control leveling device of FIG. 1.
FIG. 4 is a view showing a portion in which the driving speed sensor is located in the blade active control leveling device of FIG. 1.
5 is a view showing a process in which the driving speed sensor detects the rotational speed of the driving member.
6A is a view showing a state in which the blade active control leveling device performs a work of mowing the ground.
FIG. 6B is a side view showing a blade active control leveling device in a state in which the blade is pitched at the point a-a 'of FIG. 6A and the height of the blade is controlled.
FIG. 6C is a view showing a blade active control leveling device in a state in which the blade is rolled at the point a-a 'of FIG. 6A and the height of the left and right blades is controlled.
7 is a view showing a state in which the blade active control leveling device performs the operation of cutting the ground to a predetermined depth and accumulating soil generated in the process.
8A is a view showing a state in which the blade active control leveling device performs a task of adjusting the shape of a work target area.
FIG. 8B is a side view showing the blade active control leveling device in a state in which the blade is pitched at the point b-b 'of FIG. 8A and the height of the blade is controlled.
FIG. 8C is a view showing a blade active control leveling device in a state in which the blade is rolled at the point b-b 'of FIG. 8A and the height of the left and right blades is controlled.
9 is a view showing a state in which the blade active control leveling device performs the operation of spreading the soil located on one side of the work target area on the ground.
10 is a flowchart illustrating a process in which the attitude of the understanding blade is controlled in the information provided by the driving speed sensor.
11 is a view showing a blade active control leveling device that performs a task while the bottom of the blade is positioned at a set height.
12 is a view showing a state in which the height of the blade is adjusted when the sensed load exceeds the reference load.
13 is a view showing a state in which the height of the blade is adjusted when the sensed load is less than the reference load.
14 is a view showing a state in which the height of both ends of the blade is individually adjusted.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The embodiments of the present invention can be modified in various forms, and the scope of the present invention should not be interpreted as being limited to the following embodiments. This embodiment is provided to more fully describe the present invention to those skilled in the art. Therefore, the shape of the elements in the drawings has been exaggerated to emphasize a clearer explanation.

1 is a view showing a blade active control leveling device according to an embodiment of the present invention.

Referring to FIG. 1, the blade active control leveling device 10 includes a main body 100, a traveling member 110, a blade 200, and a driving unit 400.

Hereinafter, the front-rear direction in which the main body 100 and the blade 200 are arranged based on when the blade active control leveling device 10 is positioned on the horizontal plane is referred to as a first direction (1), and is located on the horizontal plane and is first The left-right direction (or the width direction) perpendicular to the direction 1 is referred to as the second direction 2, and the up-down direction perpendicular to the horizontal plane is called the third direction 3. In addition, in describing the configuration of the blade active control leveling device 10 in FIGS. 1 to 3, description will be made based on when the blade active control leveling device 10 is positioned on a horizontal plane.

The blade active control leveling device 10 performs a setting operation on soil on the ground. For example, the blade active control leveling device 10 may perform a task of mowing the soil on the top of the ground while driving, or a task of unfolding the soil located on one side on the ground.

The body 100 may provide a skeleton of the blade active control leveling device 10. The body 100 may be provided to have a set volume. The body 100 may have a boarding space for a user to operate the blade active control leveling device 10. In addition, an input unit (120 in FIG. 3) capable of manipulating the operating state of the blade active control leveling device 10 may be provided in the boarding space.

The driving member 110 is connected to the main body 100 and is provided to be able to travel with respect to the ground. The blade active control leveling device 10 may be moved by the traveling of the traveling member 110. The driving members 110 may be provided on both lower portions of the body 100 in the second direction 2. For example, the driving member 110 is provided as a caterpillar, a wheel, etc., and the blade active control leveling device 10 may be a bulldozer, a wheel loader, or the like. When the driving member 110 is provided as a caterpillar, the driving member 110 is provided with a plurality of shoe plates 111 around the outer circumference, so that the shoe plate 111 can be provided with a structure that is driven as it rotates.

The blade 200 is connected to the front end of the main body 100 so as to be located in the front region of the blade active control leveling device 10, and performs setting work on the soil. The blade 200 may have a set width in the second direction 2 and a set height in the third direction 3.

FIG. 2 is a view showing the front region of the blade active control leveling device of FIG. 1.

Referring to FIG. 2, the blade 200 may be connected to the main body 100 by a connection frame 300. The front end of the connection frame 300 may be connected to the rear surface of the blade 200, and the rear end of the connection frame 300 may be connected to the main body 100.

The front end of the connection frame 300 may be rotatably connected to the rear surface of the blade 200 based on an axis provided in the third direction 3. In addition, the front end of the connection frame 300 may be rotatably provided within a set range based on an axis provided in the first direction 1 and the second direction 2. As an example, the shaft connecting the front end of the connection frame 300 and the rear surface of the blade 200 is provided in the third direction (3) in the longitudinal direction, and the shaft is provided in the form of a ball or a set clearance. Can be provided. The front end of the connection frame 300 may be connected to the center region of the second direction 2 of the blade 200.

The rear end of the connection frame 300 may be rotatably connected to the main body 100 based on an axis provided in the second direction 2. For example, the rear end of the connection frame 300 is connected to the main body 100 by a shaft provided in the second direction 2 in the longitudinal direction, so that the connection frame 300 is in the vertical direction with respect to the main body 100 Can be rotated

The rear end of the connection frame 300 is spaced a predetermined distance in the second direction 2 and may be provided in a branched structure. For example, the connection frame 300 may be provided in a U shape. In addition, each rear end of the connection frame 300 may be rotatably connected to the main body 100.

The driving unit 400 provides power to adjust the position of the blade 200. The driving unit 400 includes a pitch driving member 410, a yaw driving member 420, and a roll driving member 430.

The pitch driving member 410 is driven in a form in which the blade 200 is rotated (P, pitch, pitch) with respect to an axis provided in the second direction 2, so that the height of the blade 200 in the third direction 3 Let it be adjusted. The pitch driving member 410 may be provided in a structure that provides power for the connection frame 300 to rotate in the vertical direction with respect to the main body 100. For example, the pitch driving member 410 is provided in a cylinder structure having a variable length, one end is rotatably connected to the main body 100, and the other end is rotatably connected to the connecting frame 300. . The rear end of the connection frame 300 may be provided with a pitch connection portion 310 protruding a set length upward. In addition, the other end of the pitch driving member 410 may be connected to the pitch connection part 310.

One end of the pitch driving member 410 may be connected to the main body 100 to be rotated based on an axis provided in the second direction 2. The other end of the pitch driving member 410 may be connected to the connection frame 300 to be rotated relative to an axis provided in the second direction 2. Two pitch driving members 410 may be provided and spaced apart from each other in the second direction 2 to be connected to each of the branched rear ends of the connection frame 300 and the main body 100. When the length of the pitch driving member 410 is driven to be long, the connection frame 300 is pitched (P) downward with respect to the main body 100, and accordingly the blade 200 connected to the front end of the connection frame 300 May be pitched P downward. In addition, when the length of the pitch driving member 410 is shortened, the connection frame 300 is pitched (P) upward with respect to the main body 100, and accordingly the blade connected to the front end of the connection frame 300 ( 200) may be pitched (P) upward.

The yaw driving member 420 is driven in a form in which the blade 200 is rotated (Y, yaw, Yaw) based on an axis provided in the third direction 3, so that the direction in which the blade 200 faces is adjusted.

The yaw driving member 420 is provided with a cylinder structure having a variable length, one end is rotatably connected to the connecting frame 300, and the other end is rotatably connected to the rear surface of the blade 200. Two yaw driving members 420 are provided, and may be positioned to be spaced apart in a set distance in the second direction 2.

One end of the yaw driving member 420 may be rotatably connected to the connecting frame 300 based on an axis provided in the second direction 2. One end of the yaw driving member 420 may be connected to the pitch connection part 310. The point where one end of the yaw driving member 420 is connected may be located below the point where the other end of the pitch driving member 410 is connected.

The other end of the yaw drive member 420 may be rotatably connected to the blade 200 based on an axis provided in the third direction 3. In addition, the other end of the yaw driving member 420 may be rotatably provided within a set range based on an axis provided in the first direction 1 and the second direction 2. For example, the shaft connecting the other end of the yaw drive member 420 and the rear surface of the blade 200 is provided in the third direction (3) in the longitudinal direction, and the shaft is provided in the shape of a ball, or the set clearance It can be provided to have.

The other end of the yaw driving member 420 may be connected to a point where the connection frame 300 is connected to the blade 200 and a set distance apart in the second direction 2. The other end of the two yaw driving members 420 may be connected to the blade 200 at points opposite to each other in the second direction 2 based on the point where the connecting frame 300 is connected to the blade 200.

When the length of the yaw driving member 420 becomes longer or shorter, the blade 200 may be yaw (Y, Yaw) with respect to the connection frame 300. In addition, when two yaw driving members 420 are provided, the lengths of the two yaw driving members 420 may be adjusted such that one has a shorter length and one has a longer length.

The roll driving member 430 allows the blade 200 to be driven in the form of rotation (R, roll, roll) based on an axis provided in the first direction 1. The roll driving member 430 is provided in a cylinder structure having a variable length, one end is rotatably connected to the connecting frame 300, and the other end is rotatably connected to the rear surface of the blade 200. One end of the roll driving member 430 may be connected to the connection frame 300 such that the connection frame 300 and the blade 200 are located on the same axis in the third direction 3 and the point where the connection frame 300 is connected. For example, the front end of the connecting frame 300 may be provided with a roll connecting portion 320 protruding a set length in the upward direction. The roll connection part 320 may be located on the same straight line in the first direction 1 and the point where the connection frame 300 and the blade 200 are connected. And, one end of the roll drive member 430 is connected to the roll connection part 320, the connection frame 300 and the blade 200 can be located on the same axis in the third direction (3) with respect to the connection point have.

One end of the roll driving member 430 may be rotatably connected to the connecting frame 300 based on an axis provided in the third direction 3. In addition, one end of the roll driving member 430 may be rotatably provided within a set range based on axes provided in the first direction 1 and the second direction 2. For example, the shaft connecting the one end of the roll drive member 430 and the connecting frame 300 is provided in the third direction (3) in the longitudinal direction, and the shaft is provided in the form of a ball, or the set clearance. Can be provided.

The other end of the roll driving member 430 may be connected to the blade 200 at a point spaced apart in a second direction 2 from the one end of the roll driving member 430. The other end of the roll driving member 430 may be rotatably connected to the blade 200 based on an axis provided in the third direction 3. In addition, the other end of the roll driving member 430 may be rotatably provided within a set range based on an axis provided in the first direction 1 and the second direction 2. For example, the shaft connecting the other end of the roll drive member 430 and the blade 200 is provided in the third direction (3) in the longitudinal direction, and the shaft is provided in the form of a ball, or has a set clearance. Can be provided. When the length of the roll driving member 430 is lengthened or shortened, the blade 200 may be rolled R with respect to the connection frame 300.

FIG. 3 is a block diagram showing a control relationship of the blade active control leveling device of FIG. 1.

Referring to FIG. 3, a controller 130 may be provided to the blade active control leveling device 10. The controller 130 may control components of the blade active control leveling device 10. The controller 130 may control the driving state of the blade active control leveling device 10 using information provided by the sensor 500.

The sensor 500 may provide information to the controller 130 after sensing information regarding the state of the blade active control leveling device 10. The sensor 500 may include a position sensor 510, a blade attitude sensor 520 and a body attitude sensor 530.

The position sensor 510 is located on the blade 200 and provides information regarding the position of the point where the position sensor 510 is installed. For example, a support rod 511 having a set length is provided on the upper portion of the blade 200, and the position sensor 510 may be positioned on the support rod 511. The position sensor 510 may be provided as a GPS receiver to provide coordinate information regarding the position of a point installed on the blade 200. The position sensor 510 is spaced a predetermined distance in the second direction 2, so that the first position sensor 510a is provided in the left area of the blade 200, and the second position sensor in the right area of the blade 200 ( 510b) may be provided. The controller 130 may calculate the moving speed of the blade active control leveling device 10 through a change in the position value provided by the position sensor 510.

The blade posture sensor 520 is positioned on the blade 200 to detect the posture of the blade 200. For example, the blade posture sensor 520 is provided as an inertial measurement unit (IMU) to sense the speed, direction, gravity, and acceleration of the blade 200, through which the yaw (Y) of the blade 200 ), Roll (R), pitch (P) can be provided to be detectable.

The main body posture sensor 530 is located in the main body 100 and detects the posture of the main body 100. For example, the body posture sensor 530 is provided as an inertial measurement unit (IMU) to sense the speed, direction, gravity, and acceleration of the body 100, and through this, the yaw (Y) of the body 100 ), Roll (R), pitch (P) can be provided to be detectable.

The driving speed sensor 540 is positioned adjacent to the shoe plate 111 to sense the speed at which the driving member 110 rotates.

FIG. 4 is a view showing a portion in which the driving speed sensor is located in the blade active control leveling device of FIG. 1.

Referring to FIG. 4, the driving speed sensor 540 includes a housing 541, a first sensing unit 542a and a second sensing unit 542b. The driving speed sensor 540 may be attached to the body 100 adjacent to the driving member 110. In addition, the driving speed sensor 540 may be attached to the driving member 110 to be located inside the shoe plate 111. The driving speed sensor 540 may be located on the left and right sides of the blade active control leveling device 10, respectively. At this time, the driving speed sensor 540 located in the left area of the blade active control leveling device 10 is referred to as a first driving speed sensor 540, and the driving speed located in the right area of the blade active control leveling device 10. The sensor 540 may be referred to as a second driving speed sensor 540.

The housing 541 may be provided in a block structure having a set volume. The housing 541 has a structure distinct from the main body 100 and the traveling member 110 and may be detachably provided to the main body 100 or the traveling member 110.

The first sensing unit 542a and the second sensing unit 542b are connected to the housing 541 to protrude toward the shoe plate 111. The first sensing unit 542a and the second sensing unit 542b are provided to be spaced apart by a set distance d along a direction in which the shoe plate 111 is moved. The first sensing unit 542a and the second sensing unit 542b are provided as proximity sensors, and are provided to detect the shoe plate 111 when the shoe plate 111 is positioned within a set distance. For example, the shoe plate 111 is provided with metal, and the first sensing unit 542a and the second sensing unit 542b may be provided to detect when the metal is located within a predetermined distance. The first sensing unit 542a and the second sensing unit 542b may be provided to sense the same point on the shoe plate 111. As an example, the first sensing unit 542a and the second sensing unit 542b may be provided to detect the region most protruding from the shoe plate 111 toward the driving speed sensor 540. In addition, although not shown in the drawing, when the driving speed sensor 540 is attached to the inside of the driving member 110, the inner surface of the shoe plate 111 has at least one point along the moving direction of the driving speed sensor 540 Protruding in the direction, the first sensing unit 542a and the second sensing unit 542b may detect this when they are positioned to face an area protruding from the shoe plate 111.

5 is a view showing a process in which the driving speed sensor detects the rotational speed of the driving member.

Hereinafter, a case in which the rotational speed of the driving member 110 is sensed will be described as an example when the blade active control leveling device 10 is advanced.

Referring to FIG. 5, as the driving member 110 is rotated, a time point at which one of the shoe plates 111 is sensed by the first sensing unit 542a is generated. Thereafter, when the time has elapsed, a time point at which one of the shoe plates 111 is sensed by the second detection unit 542b is generated. The controller 130 has a distance value d spaced apart from the first sensing unit 542a and the second sensing unit 542b in the rotational direction of the driving member 110. Accordingly, the controller 130 is the time difference between the time when the shoe plate 111 is detected by the first detection unit 542a and the time when the shoe plate 111 is detected by the second detection unit 542b, and the first detection The speed at which the upper plate is moved may be calculated through the distance value d between the secondary unit 542a and the second sensing unit 542b.

When the driving member 110 is reversed, when the shoe plate 111 is first detected by the second detection unit 542b, and thereafter, when the shoe plate 111 is detected by the first detection unit 542a. Except for using the time difference of, the process of detecting the rotational speed of the driving member 110 is the same as described above, so repeated description will be omitted.

The controller 130 may control the height of the blade 200 based on the information provided by the sensor 500. The position sensor 510 may provide information regarding the position of the point where the position sensor 510 is provided to the controller 130. Information about the location provided by the location sensor 510 may include a height value for the ground. The controller 130 controls the pitch driving member 410 based on the height value provided by the position sensor 510, so that the height of the blade 200 (or the lower end of the blade 200 is spaced from the ground) Distance, or the depth of the lower end of the blade 200 toward the ground) can be adjusted.

The controller 130 may reflect the information provided by the blade attitude sensor 520 to the height control of the blade 200. The height of the blade 200 is adjusted to a pitch (P) based on the axis provided in the second direction (2), the path through which the blade 200 moves to adjust the height is provided to form an arc. Accordingly, the third direction (3) perpendicular to the ground between the position sensor 510 and the bottom of the blade 200, depending on the degree to which the blade 200 is pitch (P) and the degree to which the blade 200 is inclined to the horizontal plane (3) ) Distance will be different. Accordingly, the blade posture sensor 520 provides the controller 130 with information on the degree of pitch P based on the axis in which the blade 200 is provided in the third direction 3, and the controller 130. By reflecting this, the height of the blade 200 can be controlled. For example, the controller 130 considers the degree to which the distance in the third direction (3) between the position sensor 510 and the lower end of the blade 200 changes as the blade 200 is pitched (P), so that the blade 200 ) The height of the third direction 3 with respect to the ground at the bottom can be adjusted.

The controller 130 may control the height of the left side and the height of the right side of the blade 200 to be adjusted based on information provided by the sensor 500. The controller 130 is based on the information provided by the position sensor 510 located on the left side of the blade 200, the left side of the blade 200 becomes the set height, and the position sensor located on the right side of the blade 200 ( Based on the information provided by 510, the right side of the blade 200 may be set to a set height. To this end, the controller 130 may control the roll driving member 430 to cause the blade 200 to roll. In addition, the blade posture sensor 520 provides information on the degree to which the blade 200 is rolled (R) based on the axis provided in the first direction 1 to the controller 130, and the controller 130 By using it to control the roll drive member 430, it is possible to control the degree to which the blade 200 is a roll (R). In addition, the controller 130 through the information provided by the blade posture sensor 520 and information provided by the position sensor 510 located on both sides of the blade 200, the degree to which the blade 200 rolls (R) And the blade 200 can control the height of both sides.

The controller 130 may control the yaw driving member 420 to control the degree to which the blade 200 is yawed relative to the axis provided in the third direction 3. The controller 130 controls the yaw driving member 420, and may reflect information provided by the blade attitude sensor 520. Specifically, the yaw driving member 420 provides information regarding the degree to which the blade 200 is yaw (Y) to the controller 130, and the controller 130 based on this, the yaw (Y) of the blade 200 You can control the degree to which it becomes.

The controller 130 may reflect the information provided by the body posture sensor 530 to the posture control of the blade 200. When the main body 100 is inclined with respect to the life surface of the main body 100 by the ground on which it is located, the direction in which the main body 100 and the blade 200 are connected is inclined with respect to the horizontal surface. Accordingly, the degree to which the blade 200 is pitch P relative to the horizontal plane, the distance in the third direction 3 between the position sensor 510 and the bottom of the blade 200, the bottom and the ground of the blade 200 The spaced distance will be different. Accordingly, the controller 130 reflects the degree to which the main body 100 is inclined, so that the pitch state of the blade 200, the roll state of the blade 200, or the yaw state of the blade 200 is adjusted. ) Can be controlled.

The controller 130 may reflect information provided by the driving speed sensor 540 in the attitude control of the blade 200.

The controller 130 may include a main control unit 131 and a driving control unit 132.

The main control unit 131 may generate an electrical signal for controlling the components of the blade active control leveling device 10. In addition, the main control unit 131 receives a signal from the input unit 120, or receives a signal provided by the sensor 500, and reflects it to a signal for controlling a component of the blade active control leveling device 10. You can. For example, the main control unit 131 may include a CPU, a memory, and the like.

The driving control unit 132 may control the driving unit 400. For example, the driving control unit 132 may be provided as an electro-hydraulic valve or the like, and may be provided to adjust an operating state of the driving unit 400 according to the use of an electrical signal provided by the main control unit 131.

In addition, the controller 130, through the display unit 140, a signal input from the sensor 500, the input unit 120, etc., the control state of the blade active control leveling device 10 by the controller 130, the blade active control leveling Information such as an operating state of the device 10 may be displayed. For example, the display unit 140 may be a monitor or the like located in the boarding space.

6 to 9 are views schematically showing a state in which the blade active control leveling device performs work.

6A is a view showing a state in which the blade active control leveling device performs a work of mowing the ground.

Referring to FIG. 6A, the blade active control leveling device 10 may perform an operation (ie, cut) of cutting the current terrain PL to the design surface DS. At this time, the height difference between the current terrain PL and the design surface DS is formed lower than in the case of FIG. 5. Accordingly, the blade active control leveling device 10 is controlled so that the blade 200 is pitched downward toward the ground to move to a lowered state, so as to cut the soil corresponding to the design surface DS Can be.

At this time, the controller 130 may control the degree to which the blade 200 is pitched P based on the information provided by the position sensor 510. In addition, the controller 130 may control the degree to which the blade 200 is pitched P by considering information on the degree to which the blade 200 provided by the blade attitude sensor 520 is pitched (P). . Accordingly, in the process of moving the blade active control leveling device 10, the lower end of the blade 200 may maintain a position corresponding to the design surface DS. Thereafter, the blade active control leveling device 10 is controlled to pitch (P) the blade 200 upward, thereby stacking dirt collected on the front surface of the blade 200 in an area located outside the work area. This can be done. In addition, the controller 130 may control the roll (R) state of the blades 200 so that the heights of both sides of the blades 200 are adjusted, so that the cutting operation is performed in an inclined shape. In addition, the controller 130 may control the yaw (Y) state of the blade 200 so that the cutting operation is performed while moving the curved section.

FIG. 6B is a side view showing a blade active control leveling device in a state in which the blade is pitched at the point a-a 'of FIG. 6A and the height of the blade is controlled.

Referring to FIG. 6B, the blade active control leveling device 10 determines that the work surface WS is located below the current terrain PL according to information provided by the position sensor 510 while driving the work target area. When the blade 200 is pitched downward, it is controlled such that the lower end of the blade 200 is positioned to correspond to the working surface WS. At this time, as the blade 200 is inclined by a set angle θ1 with respect to the direction perpendicular to the horizontal plane, the distance from the bottom of the blade 200 to the position sensor 510 in the third direction 3 varies. . Accordingly, the controller 130 may calculate the distance in the third direction 3 between the sensor 510 and the lower end of the blade 200 in consideration of the angle at which the blade 200 is inclined. In addition, the controller 130 is the height of the working surface WS by subtracting the distance in the third direction 3 between the sensor 510 and the lower end of the blade 200 from the height value provided by the position sensor 510. Control can be performed to be a value. Hereinafter, the method of measuring and controlling the height of the lower end of the blade 200 through the height value provided by the position sensor 510 by the controller 130 is the same, and repeated description is omitted.

FIG. 6C is a view showing a blade active control leveling device in a state in which the blade is rolled at the point a-a 'of FIG. 6A and the height of the left and right blades is controlled.

Referring to FIG. 6C, the blade active control leveling device 10 may perform work in a state in which the working height A at the lower left of the blade 200 and the working height B at the lower right are different. For example, the blade active control leveling device 10 may perform a task of making a design surface DS having an inclined shape with respect to a horizontal surface, such as a road interchange (IC) or a curved section of the road.

To this end, the controller 130 may transmit the blade () through the height value (a ') before control provided by the first position sensor (510a) and the height value (b') before control provided by the second position sensor (510b). 200) calculates the height of the bottom left and the height of the bottom right. Then, the controller 130 rolls the blade 200 so that the lower left and right lower ends of the blade 200 are the left working height A and the right working height B, respectively. At this time, in the controller 130, the information provided by the first position sensor 510a is the left working height value (a), and the information provided by the second position sensor 510b is the right working height value (b). In the form, the blade 200 is rolled by a set angle θ2, so that the left and right heights can be adjusted. In addition, as the distance from the lower end of the blade 200 to the position sensor 510 by the angle at which the blade 200 is pitched (θ1) and the angle at which it is rolled (θ2) varies, the distance in the third direction 3 , The controller 130 may control the blade 200 such that pitch driving and roll driving of the blade 200 are interlocked and reflected.

The height that is the reference of the height value provided by the position sensor 510 is shown as a reference height (RF) for convenience. For convenience, the reference height RF is shown as being located below the working heights A and B, but this is for convenience and the positional relationship of the third direction 3 may vary.

7 is a view showing a state in which the blade active control leveling device performs the operation of cutting the ground to a predetermined depth and accumulating soil generated in the process.

Referring to FIG. 7, the blade active control leveling device 10 cuts the current terrain PL to the design surface DS, and performs the operation of accumulating soil (ie, cutting and transporting) generated in the process. You can. At this time, due to the height difference between the current terrain PL and the design surface DS, the blade active control leveling device 10 travels the work target area once, while designing the work target area from the current terrain PL. (DS) cannot be cut. Accordingly, the blade active control leveling device 10 is controlled so that the blade 200 is pitched downward toward the ground (P) to move in a lowered state, cutting the soil to control the working surface (WS) to be made Can be. At this time, the controller 130 may control the degree to which the blade 200 is pitched P based on the information provided by the position sensor 510. In addition, the controller 130 may control the degree to which the blade 200 is pitched P by considering information on the degree to which the blade 200 provided by the blade attitude sensor 520 is pitched (P). . In addition, as the blade active control leveling device 10 is moved, the controller 130 has a sensor 500 such that the position of the bottom of the blade 200 relative to the main body 100 is positioned corresponding to the working surface WS. The height of the blade 200 may be adjusted based on the information provided. In addition, when the moving speed of the blade active control leveling device 10 is lower than the set speed, the controller 130 causes the blade 200 to pitch P by a set value upward, so that the blade 200 cuts the ground. Can reduce the depth. In addition, the controller 130 controls the roll (R) state of the blades 200 so that the heights on both sides of the blades 200 are adjusted to correspond to the heights of the design surface DS, and thus the inclined form Cutting can be done. In addition, the controller 130 may control the yaw (Y) state of the blade 200 so that the cutting operation is performed while moving the curved section. Thereafter, the blade active control leveling device 10 pitches the blade 200 upward (P), so that the dirt collected on the front surface of the blade 200 is stacked in an area located outside the work area. Can be controlled. The blade active control leveling device 10 may make the current terrain PL a design surface DS by repeating the operation of stacking dirt collected on the blade 200 several times after cutting the soil.

The detailed method in which the blade 200 is controlled to be set at an angular pitch or roll is the same or similar to FIGS. 6B and 6C, and thus repeated descriptions are omitted.

8A is a view showing a state in which the blade active control leveling device performs a task of adjusting the shape of a work target area.

Referring to FIG. 8A, the blade active control leveling device 10 may perform an operation (that is, shape adjustment operation) of adjusting the shape of the current terrain PL to correspond to the design surface DS. Such a work is a task of partially adjusting the shape of the ground in a state where the height difference between the current topography PL and the design surface DS is not large. Accordingly, the amount of soil manipulated by the blade 200 is less than the above-described operation. Accordingly, the controller 130 may control the bottom of the blade 200 to be positioned to correspond to the design surface DS in the process of moving the blade active control leveling device 10. Accordingly, cut or soil spreading may be performed to correspond to the target design surface DS in response to the position of the lower end of the blade 20.

As described above, the control of the blade 200 may be automatically performed by the controller 130 according to the position of the blade active control leveling device 10 with respect to the ground to be the work object. In addition, the blade 200 may be controlled by the controller 130 in conjunction with or assisted with manipulation of the blade 200 by an input of a user operating the blade active control leveling device 10. For example, the controller 130 may input information about coordinate values for an area where a task is to be performed, tasks to be performed in an area corresponding to each coordinate value, and the like. This information may correspond to specifications for the job site. For example, cutting is performed at a depth of 2 m in the work target area corresponding to the (1,1) coordinate, cutting is made at a depth of 0.5 m in the work target area corresponding to the (2,2) coordinate, etc. Information may be input to the controller 130.

In response to this, the controller 130, if it is determined that the blade active control leveling device 10 is located on the coordinates identified as having work to be performed through the information provided by the position sensor 510, is performed at the coordinates The posture of the blade 200 may be adjusted in response to vaginal work. For example, if it is determined that the blade active control leveling device 10 is located in the area corresponding to the (1, 1) coordinates through the information provided by the position sensor 510, the controller moves the blade 200 downward. When it is determined that the pitch P is set by the set value, and the blade active control leveling device 10 is determined to be moved out of the work target area, the blade 200 is pitched upward by the set value to collect dirt in the blade 200 Stacking can be performed outside the work area. Such cutting and conveying work may be performed until the current terrain PL is cut to 2 m corresponding to the design surface DS. In addition, if it is determined that the blade active control leveling device 10 is located in the area corresponding to the (2, 2) coordinates through the information provided by the position sensor 510, the controller sets the blade 200 downward. Pitch (P) as much as possible to perform cutting, and if it is determined that the blade active control leveling device (10) has been moved out of the work area, pitch the blade (200) upward by the set value to work the soil collected in the blade (200). Stacking operations outside the target area can be made.

FIG. 8B is a side view showing the blade active control leveling device in a state in which the blade is pitched at the point b-b 'of FIG. 8A and the height of the blade is controlled.

8B, the blade active control leveling device 10 determines that the design surface DS is positioned above the current terrain PL according to the information provided by the position sensor 510 while driving the work target area. 200) is pitched upward to a set angle θ3 so that the lower end of the blade 200 is positioned to correspond to the design surface DS. In addition to the pitch direction of the blade 200 being upward, the method of controlling the blade 200 is the same or similar to that described above with reference to FIG. 6B, and thus repeated description will be omitted.

FIG. 8C is a view showing a blade active control leveling device in a state in which the blade is rolled at the point b-b 'of FIG. 8A and the height of the left and right blades is controlled.

Referring to Figure 8c, the blade active control leveling device 10, while pitching the blade 200 upward, the working height (C) at the bottom left of the blade 200 and the working height (B) at the bottom right are different You can perform your work in the done state. The controller 130 of the blade 200 through the pre-control height value c 'provided by the first position sensor 510a and the pre-control height value c' provided by the second position sensor 510b Calculating the height of the lower left and the lower right, the information provided by the first position sensor 510a becomes the left working height value c, and the information provided by the second position sensor 510b is the right working height value. The method of making (c) the blade 200 to be rolled by a set angle θ4 is the same or similar to the method described above in FIG. 6C, and repeated description will be omitted.

9 is a view showing a state in which the blade active control leveling device performs the operation of spreading the soil located on one side of the work target area on the ground.

Referring to FIG. 9, the blade active control leveling device 10 may perform an operation (ie, an unfolding operation) of spreading accumulated dirt on the ground. Unfolding occurs when the current terrain (PL) is lower than the design surface (DS). In this case, if the soil is loaded near the work target area after being transported by a separate truck, the blade active control leveling device 10 performs the work of spreading the soil on the ground. To this end, when the blade active control leveling device 10 is located where dirt is accumulated, the controller 130 pitches the blade 200 downward (P), so that the height of the blade 200 is lower than the dirt accumulated. To lose. Accordingly, dirt is positioned on the front surface of the blade 200. In this state, the blade active control leveling device 10 starts driving, so that the soil located on the front surface of the blade 200 can be spread over the work target area. In the process of moving to unfold the soil, the controller 130 may control the bottom of the blade 200 to be positioned higher than the current terrain PL. Accordingly, the soil located in front of the blade 200 may be moved out of the blade 200 through the downward direction of the blade 200, and may be spread on the current terrain PL. When the height difference between the current terrain PL and the design surface DS is less than or equal to a set value, the blade active control leveling device 10 is controlled so that the lower end of the blade 200 is positioned at a height corresponding to the design surface DS It can be controlled to move to the state. In addition, when the height difference between the current terrain PL and the design surface DS exceeds a set value, when the first operation is performed, the blade active control leveling device 10 has the blade 200 at the bottom of the current terrain PL ) And the design surface DS may be controlled to be moved in a controlled state. After this operation is performed at least once, if the height difference between the current terrain PL and the design surface DS is less than or equal to the set value, the blade active control leveling device 10 has a lower design surface at the bottom of the blade 200 It may be controlled to be moved to a state controlled to be located at a height corresponding to (DS).

Since the specific method of controlling the blade 200 to be set or pitched or rolled is the same or similar to that of FIGS. 8A and 8B, repeated description will be omitted.

FIG. 10 is a flow chart showing a process in which the attitude of the blade is controlled in the information provided by the driving speed sensor, and FIG. 11 is a view showing a blade active control leveling device performing work while the bottom of the blade is positioned at a set height to be.

10 and 11, when the blade active control leveling device 100 moves and performs work while the lower end of the blade 200 is positioned at a set height, the controller 130 has a driving speed sensor 540 Through the information provided and the information provided by the position sensor 510, it is possible to detect the load applied to the blade 200 (S100). At this time, the height of the lower end of the blade 200 in FIGS. 6 to 9 It may be a position corresponding to the above-described working surface (WS) or design surface (DS) In addition, the height of the lower end of the blade 200 is adjusted to the load amount as described later, the working surface (WS) or design surface (DS) It may be a point that is moved a set distance upward from.

The blade active control leveling device 10 moves while cutting the ground with the blade 200, or as the soil moves in a state where the soil is located on the front surface of the blade 200, the blade active control leveling device 10 has a moving direction. Resistance acts in the opposite direction. Accordingly, a slip occurs between the driving member 110 and the ground, and a difference occurs between the speed of the driving member 110 and the driving speed of the blade active control leveling device 10 provided by the position sensor 510. do. Accordingly, the controller 130 may make the difference in speed between the traveling speed and the traveling member 110 as a load amount. In addition, the controller 130 may set the slip ratio λ between the driving member 110 and the ground defined as Equation 1 as the load amount.

Vω: speed of traveling member, Vx: speed of traveling

In addition, the controller 130 may use the resistance force Fr acting on the blade defined as Equation 2 as a load amount.

M: mass of the blade active control leveling device, r: radius of the front or rear end of the traveling member, ω: angular velocity at the front or rear end of the traveling member, λ: slip rate between the traveling member and the ground, λ _d : slip rate set in the controller, Vω: speed of the traveling member

The controller 130 determines whether or not the detected load exceeds the reference load (S200). The reference load amount is a load amount set to act on the blade 200 when the blade active control leveling device 10 performs work with proper efficiency. The reference load amount may be set to a band in a set range.

If it is determined that the detected load amount is outside the reference load amount, the controller 130 performs height adjustment of the blade 200 (S300).

12 is a view showing a state in which the height of the blade is adjusted when the sensed load exceeds the reference load.

Referring to FIG. 12, when it is determined that the sensed load exceeds the reference load, the controller 130 raises the height of the blade 200. Accordingly, the degree to which the blade 200 enters the ground may be reduced, or the distance between the blade and the ground may be increased, so that the degree of the soil located at the front of the blade passing out between the bottom of the blade and the ground may be increased. Accordingly, the load applied to the blade active control leveling device 10 can be reduced. The height at which the blade 200 is raised may correspond to the size of a value in which the sensed load exceeds the reference load.

13 is a view showing a state in which the height of the blade is adjusted when the sensed load is less than the reference load.

Referring to FIG. 13, when it is determined that the detected load amount is less than the reference load amount, the controller 200 lowers the height of the blade 200. Accordingly, the degree to which the blade 200 enters the ground is increased, or the distance between the blade 200 and the ground is reduced, so that the soil located at the front of the blade passes between the bottom of the blade 200 and the ground. Can be reduced. Accordingly, the load applied to the blade active control leveling device 10 can be increased. The degree to which the blade 200 descends may correspond to the size of a value in which the detected load amount is less than the reference load amount. When the blade 200 is lowered, the height of the lower end of the blade 200 may be limited to a height corresponding to the above-described working surface WS or design surface DS.

14 is a view showing a state in which the height of both ends of the blade is individually adjusted.

Referring to FIG. 14, the controller 130 calculates a load applied to the left region of the blade active control leveling device 10 through information provided by the first position sensor 510a and the first drive speed sensor 540 and , Through the information provided by the second position sensor 510b and the second driving speed sensor 540, it is possible to calculate the load applied to the right region of the blade active control leveling device 10. Accordingly, the controller 130 adjusts the height of the left area of the blade 200 and compares the load in the right area with the reference load when it is determined that the load in the left area is out of the reference load by comparing the load in the left area with the reference load If it is determined to be out of range, the height of the right area of the blade 200 may be adjusted. Accordingly, the height of both sides or one side of the blade 200 is adjusted, so that the heights of both ends of the blade 200 may be different. To this end, the controller 130 may perform control such that the blade is roll driven or roll driven and pitch driven.

As described above, the process in which the controller 130 detects the load amount and compares the sensed load amount with the reference load amount, and controls the height of the blade 200 is provided in the form of a closed loop, and the blade active control leveling device 10 ) May be repeatedly performed at least once while performing the operation while driving. Accordingly, the blade active control leveling device 10 is in a state in which the blade active control leveling device 10 is actually moved and the height of the blade 200 is adjusted to an appropriate range in preparation for the speed of the driving member 110. You can work effectively while driving.

Blade active control leveling device 10 according to an embodiment of the present invention is automatically or through the information provided by the sensor 500 to assist the user's manipulation, the attitude of the blade 200 is adjusted, blade active control leveling The work can be done efficiently through the device 10.

In addition, the blade active control leveling device 10 according to an embodiment of the present invention can effectively adjust the height of the blade 200 through the information provided by the position sensor 510.

In addition, in the blade active control leveling device 10 according to an embodiment of the present invention, the heights of both sides of the blade 200 may be adjusted through the position sensors 510 provided on both sides of the blade 200.

In addition, the blade active control leveling device 10 according to an embodiment of the present invention is the height of both sides of the blade 200 and the blade 200 is rolled through the blade attitude sensor 520 located in the blade 200 The degree can be adjusted.

In addition, the blade active control leveling device 10 according to an embodiment of the present invention takes into account the degree to which the main body 100 is inclined through the main body posture sensor 530 provided in the main body 100. Posture can be adjusted.

The above detailed description is to illustrate the present invention. In addition, the above-described content is to describe and describe preferred embodiments of the present invention, and the present invention can be used in various other combinations, modifications and environments. That is, it is possible to change or modify the scope of the concept of the invention disclosed herein, the scope equivalent to the disclosed contents, and / or the scope of the art or knowledge in the art. The embodiments described describe the best state for implementing the technical idea of the present invention, and various changes required in specific application fields and uses of the present invention are possible. Accordingly, the detailed description of the invention is not intended to limit the invention to the disclosed embodiments. In addition, the appended claims should be construed to include other embodiments.

100: body 110: running member
200: blade 300: connecting frame
400: drive unit 410: pitch drive member
420: yaw drive member 430: roll drive member

Claims (12)

A body having a set volume;
A traveling member provided on both lower portions of the main body and provided to be movable with respect to the ground;
A blade having a set width and a set height and connected to the front end of the body;
A drive unit that provides power to adjust the position of the blade;
A position sensor located on the blade to provide position information of a point installed on the blade;
A driving speed sensor positioned on the main body or the traveling member and sensing a rotational speed of the traveling member; And
And a controller for controlling the drive unit such that the height of the blade is adjusted through information provided by the position sensor and the drive speed sensor. According to claim 1,
The driving member is a blade active control leveling device provided as a caterpillar having a plurality of shoe plates around the outside. According to claim 2,
The drive speed sensor
housing;
A first sensing unit connected to the housing to protrude toward the shoe plate; And
Blade active control leveling device including a second sensing unit connected to the housing to protrude toward the shoe plate. According to claim 3,
The first sensing unit and the second sensing unit blade active control leveling device provided to be spaced apart a set distance along the direction in which the shoe plate is moved. According to claim 3,
The first detection unit and the second detection unit is a blade active control leveling device provided as a proximity sensor to detect when the shoe plate is located within a set distance. According to claim 1,
The controller calculates the load applied to the blade through the movement speed calculated through the position information provided by the position sensor and the rotational speed of the driving member provided by the driving speed sensor, and the blade according to the size of the load Blade active control leveling device that allows the height of the blade to be adjusted. The method of claim 6,
The controller is a blade active control leveling device for controlling the drive unit so that the height of the blade rises when the load exceeds a predetermined reference load. The method of claim 6,
The controller is a blade active control leveling device for controlling the drive unit so that the height of the blade is lowered when the load amount is less than a predetermined reference load amount. The method of claim 6,
The position sensor,
A first position sensor located in the left area of the blade; And
It includes a second position sensor located in the right area of the blade,
The driving speed sensor,
A first driving speed sensor located in the left region; And
Blade active control leveling device comprising a second drive sensor located in the right area. The method of claim 9,
The controller adjusts the height of the left area of the blade through the information provided by the first position sensor and the first drive speed sensor, and the information is provided by the second position sensor and the second drive sensor. Blade active control leveling device that adjusts the height of the right area of the blade. The method of claim 6,
The controller is a blade active control leveling device for calculating the load while the work is being performed, and repeatedly performing the step of adjusting the height of the blade in a closed loop structure. According to claim 1,
The drive speed sensor is a blade active control leveling device provided detachably.

Images