KR101139342B1 - Flipper assembly for mobile robot - Google Patents

Abstract

PURPOSE: A flipper for a mobile robot is provided to improve pulling force by increasing the contact area of a drive belt and the ground and to improve the mobility of a mobile robot reagardless of topographcial conditions. CONSTITUTION: A flipper for a mobile robot comprises a main wheel assembly, a drive shaft(30), a main bracket(50), a sub wheel assembly(20), and a drive belt(40). The main wheel assembly is meshed with a main shaft of a robot body and is rotated. The drive shaft is integrally connected to a sub shaft of the robot body and rotatably supports the main wheel assembly. The main bracket supports the main wheel assembly and is rotated by the drive shaft. The sub wheel assembly is rotatably coupled to a driven shaft installed in the other side of the main bracket. The drive belt is coupled to the outer surfaces of the main and sub wheel assemblies and is moved along the outer surface of a guide(55) of the main bracket.

Description

Flipper Assembly for Mobile Robot

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flipper for a mobile robot that facilitates movement of a mobile robot by rotating within a certain range in response to various types of ground surface in a track or wheel type mobile robot utilized in a disaster area or a military area. It relates to a mobile robot flipper for stabilizing the movement of the mobile robot by improving the mobility of the mobile robot by using the elastic member to always be in close contact with the ground instead of using a separate control means.

In general, various types of mobile robots equipped with various sensing means or cameras are used to identify a disaster area or reconnaissance activity in a military area. Most of these mobile robots receive control signals by remote controllers. There are various types of mobile robots selectively used according to the environment.

In general, mobile robots use tracks or wheels as a means of movement. In the case of pavement or flat terrain, they use wheels for fast maneuvering. I'm using In particular, in the case of a mobile robot that needs to move on irregular ground due to a staircase or various obstacles, a flipper which is rotatable within a predetermined range is mounted on each corner of the mobile robot, and the flipper is brought into close contact with the ground in real time with a certain pressure. It also improves grip and improves the mobility of mobile robots.

As shown in FIG. 1, a mobile robot having a conventional flipper includes a robot body 100 having a pulley 131 and a track 130 including a belt 132 installed at both sides thereof, and the track 130. The main shaft 110 is installed on the outside and the flipper 200 is operated in conjunction with each pulley 131, the main body 110 is installed on the robot body 100 to drive the track 130 and the flipper 200 at the same time. And a sub shaft 120 installed at the robot body 100 to rotate the flipper 200. In this case, the main shaft 110 and the sub shaft 120 is generally formed in a concentric shaft structure.

The mobile robot having the conventional flipper configured as described above is moved by the flipper 200 when the robot main body 100 is moved by the main shaft 110 and moved by the controller if the surface conditions such as stairs are changed. The sub shaft 120 is driven to rotate the entire flipper 200 in the forward or reverse direction so that the robot body 100 can move smoothly regardless of the terrain conditions.

However, the above-described conventional mobile robot having a flipper has a problem in that a driving device capable of driving the sub shaft according to ground conditions and a control means for controlling the flipper are required to closely contact the ground surface.

In addition, as the subshaft is driven using the driving device and the control means, there is another problem that the operating time of the mobile robot is ultimately reduced due to energy consumption due to the driving of the subshaft.

That is, the mobile robot preferably moves in a state in which the robot body is in close contact with the ground, and it is necessary to control the track of the flipper to always be in close contact with the ground. Therefore, it is necessary to control the operation of the sub shaft for rotating the flipper by sensing the environment of the ground surface. However, because a lot of energy is consumed in this process, ultimately the operating time of the mobile robot driven by the storage battery is reduced.

The present invention has been made to solve the above-mentioned conventional problems, and instead of operating the sub-shaft of the robot body, instead of operating the sub-shaft of the robot body by pressing the flipper to always be in close contact with the ground surface by lowering the height of the robot body installed with the flipper robot body stable The purpose of the present invention is to provide a flipper for a mobile robot that can improve the mobility of the mobile robot regardless of terrain conditions by improving the grip force.

Another object of the present invention is to provide a flipper for a mobile robot in which the flipper comes into close contact with the ground even when the bracket of the flipper does not rotate about the drive shaft in response to the ground surface environment.

In addition, the present invention provides a variety of structures of the flipper to exert an elastic force so that the flipper is always in close contact with the ground to automatically adjust the position of the flipper by mechanical force without using a separate flipper drive means, according to the need An object of the present invention is to provide a flipper for a mobile robot, which enables a user to select and use a flipper in a form.

The present invention for achieving the above object is provided in the robot main body of the mobile robot moving along the ground to enable the robot body to be started regardless of the surface conditions, the robot provided in the robot body A main wheel assembly engaged with the main shaft and rotating; A drive shaft integrally connected with the sub shaft of the robot body and rotatably supporting the main wheel assembly; A main bracket supporting the main wheel assembly and being rotated by the drive shaft; A sub wheel assembly rotatably coupled to a driven shaft installed on the other side of the main bracket; And a driving belt coupled to an outer circumferential surface of the main wheel assembly and the sub wheel assembly and generating a driving force while moving along the outer surface of the guide attached to the main bracket.

The main wheel assembly may include a driving wheel having a gear unit engaged with the main shaft on one side, a driven wheel installed on the opposite side of the driving wheel with the main bracket interposed therebetween, between the driving wheel and the driven wheel, and the driving shaft. And an elastic device assembly having bearings installed on the driving shafts and elastic means for urging the main bracket so that the sub wheel assembly portion always faces the ground by using elasticity.

Here, the elastic means is characterized in that the preloaded spring member is given a predetermined elastic force in advance.

In addition, according to the flipper for a mobile robot of the present invention, the elastic device assembly is installed on the drive shaft and the inner bracket to receive the end of the main bracket on one side, and to cover the end of the main bracket accommodated in the inner bracket An outer bracket coupled to the inner bracket, an elastic spring inserted into a plurality of arc-shaped through holes formed in the main bracket, and installed on one side of the inner bracket and the outer bracket so as to pass through the arc-shaped through hole, It characterized in that it comprises a connecting pin for pressing the elastic spring.

In addition, according to the flipper for the mobile robot of the present invention, the diameter of the elastic spring is larger than the thickness of the main bracket, characterized in that the inner bracket and the outer bracket is formed with a spring mounting groove for receiving a portion of the elastic spring. do.

In addition, according to the flipper for the mobile robot of the present invention, the inner bracket and the outer bracket are coupled to each other by a flat head screw, the head of which is not exposed to the outside.

In addition, according to the flipper for the mobile robot of the present invention, the elastic device assembly, the inner bracket and the outer bracket which is installed on the drive shaft and accommodates the end of the main bracket on one side, and a plurality of arc-shaped through holes formed in the main bracket It is characterized in that it comprises a connecting pin which is installed on any one of the inner bracket and the outer bracket so as to pass through and coupled to the other side, the leaf spring is installed on the main bracket and elastically deformed by the connecting pin.

In addition, according to the flipper for mobile robot of the present invention, the elastic device assembly, the inner bracket and the outer bracket which is installed on the drive shaft and the end of the main bracket is received at one side, and a plurality of arc-shaped through holes formed in the main bracket It is characterized in that it comprises a connection pin which is installed on any one of the inner bracket and the outer bracket so as to penetrate through and coupled to the other side, and a spring spring installed on the main bracket and elastically deformed by the connection pin.

In the mobile robot flipper of the present invention, the main bracket is rotated to the ground surface direction by using the elastic force generated by the elastic means, so that the area in which the drive belt of the flipper comes in contact with the ground increases the traction force, and the main bracket moves against the drive shaft. In the case of relative rotation, the main bracket is returned to the initial position by the elastic force of the elastic means, so that the moving height of the robot is kept relatively low to enable stable movement, and the flipper is always in close contact with the ground to improve the grip force and the terrain conditions. Irrespective of this, the mobility of the mobile robot is improved.

In addition, according to the flipper for the mobile robot of the present invention, since the elastic member of the resilient means returns the main bracket rotated according to the shape of the ground surface, it does not consume energy for rotating the main bracket, thereby moving the mobile robot. The effect is longer.

In addition, according to the flipper for the mobile robot of the present invention, since the pressure is applied to the main bracket by the preloaded elastic spring member, the main bracket always faces the ground, so that the track portion of the flipper is always in close contact with the ground, as well as the robot body. The main bracket rotates up and down within a certain range irrespective of the sub-shaft, so that it is possible to cope with the shape change of the ground surface.

1 is a reference diagram showing a general structure of a mobile robot equipped with a flipper.
Figure 2 is a perspective view showing a flipper for a mobile robot according to the present invention.
3 is an exploded perspective view of a flipper for a mobile robot according to the present invention;
4 is an exploded perspective view of an elastic device assembly which is a main component of the present invention.
Figure 5 is a vertical sectional view of the main wheel assembly, which is a main component of the present invention.
6 is a longitudinal cross-sectional view of the main wheel assembly, which is a main component of the present invention;
Figure 7 is a reference diagram for explaining the elastic action of the elastic spring in the elastic device assembly of the main component of the present invention, (a) is a state in which the flipper is lowered to the maximum by the terrain conditions, the sub-wheel assembly portion is rotated downward And (b) shows the state when the flipper is fully pressed by the terrain conditions and the sub-wheel assembly portion is rotated upward.
8 is a schematic view showing a second embodiment of an elastic device assembly which is a main component of the present invention;
Figure 9 is a schematic diagram showing a third embodiment of an elastic device assembly which is a main component of the present invention.
10 is a reference diagram showing the direction of action of the force of the mobile robot is installed flipper for mobile robot of the present invention.

Hereinafter, a flipper for a mobile robot of the present invention will be described with reference to the accompanying drawings.

The flipper for a mobile robot according to the present invention is a device installed in the robot main body 100 of a mobile robot moving along the ground, so that the robot main body 100 can be started regardless of the shape condition of the ground. Since the excepted mobile robot part is the same as the mobile robot shown in FIG. 1, the reference numeral of FIG. 1 will be used for the mobile robot-related configuration.

2 and 3, the flipper for the mobile robot of the present invention includes a main wheel assembly 10 which is engaged with and rotates to the main shaft 110 provided in the robot body 100; A drive shaft (30) integrally connected to the sub shaft (120) of the robot body (100) and rotatably supporting the main wheel assembly (10); A main bracket (50) supporting the main wheel assembly (10) and rotated by the drive shaft (30); A sub wheel assembly (20) rotatably coupled to a driven shaft (25) installed on the other side of the main bracket (50); A driving belt 40 coupled to the outer circumferential surfaces of the main wheel assembly 10 and the sub wheel assembly 20 and generating a driving force while moving along the outer surface of the guide 55 attached to the main bracket 50; It is made to include.

In addition, the main wheel assembly 10 includes a driving wheel 11 having a gear part 12 on which one of the main shafts 110 is engaged, and the driving wheel with the main bracket 50 interposed therebetween. On the driven wheel 13 provided on the opposite side of the (11), the bearing 14 provided between the drive wheel 11 and the driven wheel 13 and the drive shaft 30, and the drive shaft 30 And an elastic device assembly 60 having elastic means for urging the main bracket 50 so that the sub wheel assembly 20 is always facing the ground by using elasticity.

At this time, the elastic means is a preloaded spring member that is given a predetermined elastic force in advance, as shown in Figure 10 the main bracket 50 is pressed to the ground. Therefore, the main bracket 50 is rotated within a predetermined range in the vertical direction to correspond to the shape change of the ground surface.

In particular, the elastic device assembly 60 is installed on the drive shaft 30, as shown in Figures 4 to 6, the inner bracket 61 is received at one end of the main bracket 50 on one side, and the inner Inserted into the outer bracket 62 coupled to the inner bracket 61 and the plurality of arc-shaped through holes 52 formed in the main bracket 50 so as to cover the end of the main bracket 50 accommodated in the bracket 61. Is installed on any one of the inner bracket 61 and the outer bracket 62 to pass through the elastic spring 65 and the arc-shaped through hole 52 is coupled to the other side and pressurizing the elastic spring 65 It is configured to include a pin (63).

Here, the diameter of the elastic spring 65 is preferably larger than the thickness of the main bracket 50. In this case, it is obvious that the inner bracket 61 and the outer bracket 62 should have spring mounting grooves 61 ′ and 62 ′ in which a part of the elastic spring 65 is accommodated. As such, increasing the diameter of the elastic spring 65 to the thickness of the main bracket 50 allows the elastic spring 65 to secure sufficient elastic force, while increasing the thickness of the main bracket 50 to increase the weight. This is to prevent the increase.

In addition, the inner bracket 61 and the outer bracket 62 are preferably coupled to each other by a flat head screw 64, the head of which is not exposed to the outside to be integrally rotated. This is due to the fastening means for coupling the inner bracket 61 and the outer bracket 62, the distance between the drive wheel 11 and the driven wheel 13 is spaced more than necessary to increase the width of the drive belt 40 It is to prevent that.

The flipper for a mobile robot of the present invention configured as described above is attached to the robot body of the mobile robot so that the mobile robot can start regardless of the terrain regardless of the terrain change of the ground surface.

When the robot body 100 moves, the driving wheel 11 provided with the gear part 12 engaged with the main shaft 110 rotates, and is coupled to the outer circumferential surface of the driving wheel 11 and the driven wheel 13. The driven belt 40 moves along the outer surface of the guide 55 of the main bracket 50 to generate a driving force. Therefore, the robot body 100 and the flipper are driven integrally and move.

If the mobile robot moves on a flat terrain instead of a slope, the main shaft 50 of the flipper is rotated upward by rotating the driving shaft 30 using the sub shaft 120. Accordingly, the sub wheel assembly 20 of the flipper is separated from the ground to reduce frictional resistance, thereby smoothing the movement of the mobile robot. At this time, the inner bracket 61 and the outer bracket 62 of the elastic device assembly 60 to which the ends of the main bracket 50 are coupled are rotated together with the main bracket 50.

However, when the main bracket 50 is rotated upward due to the terrain conditions in the state that the sub shaft 120 is not rotated, the inner bracket installed on the drive shaft 30 integrally formed with the sub shaft 120. The 61 and the outer bracket 62 are not rotated, so that the elastic spring 65 installed in the arc through hole 52 of the main bracket 50 is the inner bracket 61 and the outer bracket 62. It is compressed by the connecting shaft (63) for connecting. And since the pressure is applied to the main bracket by the elastic force of the elastic spring 65, the drive belt 40 of the flipper maintains a state in close contact with the ground. As such, even when the main bracket 50 is rotated upward, the track 130 of the robot body 100 and the driving belt 40 of the flipper continue to rotate, and thus, the robot body 110 acts as a flipper. You can maneuver regardless of terrain conditions.

Then, when the terrain condition is changed again, the main bracket 50 is returned to the initial position by the elastic force of the elastic spring 65, and the main wheel assembly 10 in which the elastic device assembly 60 is installed is reversed. Will rotate.

That is, when the main bracket 50 is rotated upward due to the terrain condition, the main bracket 50 is provided in the elastic device assembly 60 without directly controlling the position of the main bracket 50 by using the sub shaft 120. By using the elastic force of the elastic spring 65 is to return the main bracket 50 to the initial position. Therefore, it is not necessary to directly adjust the flipper according to the change of the terrain condition, so that the control of the mobile robot becomes easy, and the driving of the sub shaft 120 for adjusting the position of the flipper becomes unnecessary. As a result, it is possible to save the energy driving the sub shaft 120 according to the terrain conditions can be used for the control of the mobile robot increases the operating time of the mobile robot.

Meanwhile, as shown in FIG. 8, the elastic device assembly 60 ′ is installed on the drive shaft 30 and the inner bracket 61 and the outer bracket 62 are accommodated at one end of the main bracket 50. And a connection pin 63 installed on one side of the inner bracket 61 and the outer bracket 62 so as to pass through the plurality of arc-shaped through holes 52 formed in the main bracket 50 and coupled to the other side. It may be configured to include a leaf spring 66 is installed on the main bracket 50 and elastically deformed by the connecting pin 63 (second embodiment).

In this case, except that energy according to the rotation of the main bracket 50 is stored as elastic energy in the leaf spring 66, the same as the first embodiment using the elastic spring 65 as a preloaded elastic spring member Since it is so different, a detailed description of the operation relationship will be omitted.

In addition, as shown in FIG. 9, the elastic device assembly 60 ″ is installed on the drive shaft 30 and the inner bracket 61 and the outer bracket 62 accommodated at one end of the main bracket 50. And a connection pin 63 installed on one side of the inner bracket 61 and the outer bracket 62 so as to pass through the plurality of arc-shaped through holes 52 formed in the main bracket 50 and coupled to the other side. In addition, the main bracket 50 may be installed to include a spring spring 67 elastically deformed by the connecting pin 63 (third embodiment).

In this case, the first embodiment also uses the elastic spring 65 as a preloaded elastic spring member, except that energy according to rotation of the main bracket 50 is stored as elastic energy in the spring spring 67. Since it is similar to the second embodiment using the leaf spring 66, a detailed description of the operation relationship will be omitted.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, Changes will be possible.

10: main wheel assembly
11: drive wheel 12: gear part
13: driven wheel 14: bearing
20: sub wheel assembly
25: driven shaft
30: drive shaft
40: drive belt
50: main bracket 52: arc through hole
55: guide
60, 60 ', 60 ": elastomeric assembly
61: inner bracket 62: outer bracket
61 ': spring loaded groove 62': spring loaded groove
63: connecting pin 64: flat head screw
65: elastic spring 66: leaf spring
67: self-winding spring
100: robot body
110: main shaft 120: sub shaft
130: track

Claims (7)

In the robot main body 100 of the mobile robot moving along the ground in the flipper for the mobile robot to enable the robot body 100 to be started regardless of the terrain conditions of the surface,
A main wheel assembly 10 engaged with the main shaft 110 provided in the robot body 100 and rotating; A drive shaft (30) integrally connected to the sub shaft (120) of the robot body (100) and rotatably supporting the main wheel assembly (10); A main bracket (50) supporting the main wheel assembly (10) and rotated by the drive shaft (30); A sub wheel assembly (20) rotatably coupled to a driven shaft (25) installed on the other side of the main bracket (50); A driving belt 40 coupled to the outer circumferential surfaces of the main wheel assembly 10 and the sub wheel assembly 20 and generating a driving force while moving along the outer surface of the guide 55 attached to the main bracket 50; Including,
The main wheel assembly 10 has a driving wheel 11 having a gear portion 12 on which one of the main shafts 110 is engaged, and the driving wheel 11 with the main bracket 50 interposed therebetween. A driving wheel 13 installed on the opposite side of the driving wheel, a bearing 14 installed between the driving wheel 11 and the driving wheel 13, and the driving shaft 30, and the driving shaft 30, And an elastic device assembly having elastic means for urging the main bracket (50) so that the sub wheel assembly (20) is always faced to the ground. The method of claim 1,
The elastic means is a flipper for a mobile robot, characterized in that the preloaded spring member is given a predetermined elastic force in advance. The method according to claim 1 or 2,
The elastic device assembly 60 is installed on the drive shaft 30, the inner bracket 61 is accommodated at one end of the main bracket 50, the main bracket 50 accommodated in the inner bracket 61 An outer bracket 62 coupled to the inner bracket 61 so as to cover an end portion thereof; an elastic spring 65 inserted into a plurality of arc-shaped through holes 52 formed in the main bracket 50; It is characterized in that it comprises a connecting pin 63 is installed on any one of the inner bracket 61 and the outer bracket 62 so as to penetrate the ball 52 and coupled to the other side and press the elastic spring 65. Flipper for mobile robot. The method of claim 3,
A diameter of the elastic spring 65 is larger than the thickness of the main bracket 50, the spring mounting groove 61 'in which a portion of the elastic spring 65 is accommodated in the inner bracket 61 and the outer bracket 62. Flipper for mobile robot, characterized in that (62 ') is formed. The method of claim 3,
The inner bracket (61) and the outer bracket (62) is coupled to each other by a flat head screw (64), the head is not exposed to the outside, the mobile robot flipper, characterized in that the rotation. The method according to claim 1 or 2,
The elastic device assembly 60 ', the inner bracket 61 and the outer bracket 62 and the main bracket 50, which is installed on the drive shaft 30, the one end of the main bracket 50 is accommodated on one side; Connection pins 63 installed on one side of the inner bracket 61 and the outer bracket 62 and coupled to the other side so as to penetrate the plurality of arc-shaped through holes 52 formed in the second bracket and the main bracket 50. And a leaf spring (66) elastically deformed by the connection pin (63). The method according to claim 1 or 2,
The elastic device assembly 60 ″, an inner bracket 61 and an outer bracket 62 mounted to the drive shaft 30 and accommodating an end portion of the main bracket 50 on one side thereof, and the main bracket 50. Connection pins 63 installed on one side of the inner bracket 61 and the outer bracket 62 and coupled to the other side so as to penetrate the plurality of arc-shaped through holes 52 formed in the second bracket and the main bracket 50. And a spring spring 67 that is elastically deformed by the connection pin 63.

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