KR100728744B1 - Crawling Device Capable of Minimizing Rotation Radius - Google Patents

Abstract

The present invention relates to a crawler traveling device that can minimize the radius of rotation.

Crawling traveling device of the present invention,

A flat plate-shaped base plate; A front wheel shaft rotatably installed by the first hinge on the base plate and provided with a front wheel; A rear wheel shaft rotatably installed by a second hinge on the base plate, the rear wheel being installed;

A driving device installed at the front wheel or the rear wheel to drive the front wheel or the rear wheel; A coupling member coupled to the front wheel shaft and the rear wheel shaft to collect the front wheel and the rear wheel in a direction to be rotated to facilitate rotation; And a control device for alternately applying a control pulse signal to the driving device to control the traveling device to perform a crawling operation.

By using the present invention as described above, it is possible to minimize the radius of rotation of the crawling traveling device to be able to smoothly travel along the travel path even if the path is sharply bent during driving.

Drive, link, drive motor, reducer

Description

Crawling Device Capable of Minimizing Rotation Radius

1 is a bottom structural view of a crawler traveling device of the prior art

Figure 2 is a lower structural diagram when rotating in the prior art of Figure 1

Figure 3 is a lower structural diagram of the crawler driving apparatus of the present invention

4 and 5 are lower structural diagrams when the crawler driving apparatus of the present invention according to FIG.

FIG. 6 illustrates a method of applying a control signal for a crawler driving apparatus of the present invention according to FIG. 3.

7 is a lower structural diagram of a crawler according to another embodiment of the present invention

The present invention relates to a crawler traveling device that can minimize the radius of rotation.

In general, most driving toys such as driving toys simulate the running or walking motion of a car or a human / animal, and do not require crawling.

However, since insects or turtles are crawling, in order to implement a simulated toy, a special driving device capable of realizing crawling is required.

For a traveling device that implements such a crawling operation, the present applicant has proposed a crawling driving device as shown in FIG. 1 in a preceding application (Patent Application 2005-23936).

In this prior art, the front wheel 9 is alternately moving to the left and right to implement the crawling movement, and when the rotation is desired to move a lot in the direction to rotate and less in the direction that does not want to rotate ultimately rotation The operation of crawling in the direction of For further details, see the preceding application.

By the way, in the prior art, as shown in Fig. 2, the front wheel 9 is easily rotated when the traveling device 5 rotates, but the rear wheel 14 is placed vertically, and the rear wheel 14 is Since the side of the rear wheel 14 must be rotated while the side of the rear wheel 14 is rubbing against the inner side of the support structure 9, the rotation is not smooth and the rotation radius cannot be made very small.

When the radius of rotation is increased in this way, the track that the traveling device 5 should travel on is sharply off the track, and the rotation is not smooth, and the rotation takes much time. That is, in the traveling device 5 of the prior art according to Figure 1 has a disadvantage that the rotation radius of the traveling device 5 is large, the rotation is not smooth.

Meanwhile, in another conventional embodiment, there is no arm 10 as shown in FIG. 1, and motors for the left and right front wheels are installed, respectively, and when the rotation is performed, a signal is applied to one motor for a long time and a signal for a short time is applied to the other motor. The direction of rotation is changed by different rotation speeds of both wheels, but in this prior art, the crawling operation cannot be performed.

The present invention is to solve the above problems, in the operating toy or the traveling device for a small robot, to provide a traveling device to smooth the rotation by minimizing the rotation radius of the traveling device while performing the crawling operation.

In order to achieve the object of the present invention as described above,

Crawling traveling device of the present invention,

A flat plate-shaped base plate;

A front wheel shaft rotatably installed by the first hinge on the base plate and provided with a front wheel;

A rear wheel shaft rotatably installed by a second hinge on the base plate, the rear wheel being installed;

A driving device installed at the front wheel or the rear wheel to drive the front wheel or the rear wheel;

 A coupling member coupled to the front wheel shaft and the rear wheel shaft to collect the front wheel and the rear wheel in a direction to be rotated to facilitate rotation;

And a control device for alternately applying a control pulse signal to the driving device to control the traveling device to perform a crawling operation.

First, the configuration of the running toy gear thinning traveling device according to an embodiment of the present invention will be described with reference to FIG.

In the lower part of the traveling device of the present invention,

The left and right wheels 20L and 20R of the front wheel, the driving motors 21L and 21R, and the reducers 22L and 22R which decelerate the rotation generated by the motors 21L and 21R, have motors 21L and 21R. The driving force 23 is driven by decelerating the rotational power of the vehicle by the reduction gears 22L and 22R and transmitting the reduced rotational force to the driving wheels 20L and 20R.

That is, the traveling device 23 incorporating the motors 21L and 21R lowers the number of revolutions of the motors 21L and 21R through the reduction gears 22L and 22R and increases driving force to drive the traveling device 23. Let's go.

Of course, although not shown, the upper portion of the traveling device 25 can be equipped with a battery or a rechargeable battery for supplying current to the motors 21L and 21R, and a control device and a power on / off switch.

In addition, the center of the front wheel shaft 24 is coupled to be freely rotatable about the hinge 26 of the base plate 25.

The rear wheels 27L and 27R are rotatably coupled to the center of the rear wheel shaft 28 about the hinge 29 of the base plate 25 in the same manner as the front wheels 20L and 20R.

In addition, the front wheel shaft 24 and the rear wheel shaft 28, as shown in Figure 3, each end of the link coupled to the hinge 31, 32 of the front wheel shaft 24 and the rear wheel shaft 28 in a link structure 30 is installed at an angle.

Now, the crawling operation of the traveling device 23 of the present invention will be described with reference to FIGS. 4 and 5.

First, the forward straight operation will be described.

As described above, in the state where the crawling driving device 23 of the present invention is formed, the forward current waveform having the waveform as shown in Fig. 6A is applied to the left and right motors 21L and 21R by the control device.

 Then, the front wheels 20L and 20R alternately rotate left and right at the same angle with each application of the left and right pulses, so that the front wheels advance in the same distance in the zigzag manner from the left and the right in the forward direction, and eventually go straight forward in a zigzag manner. 4 illustrates a state in which the left forward pulse is movable to the right front.

At this time, since the front wheel shaft 24 and the rear wheel shaft 28 are inclined clockwise and counterclockwise, respectively, by the link 30, the crawling shape of the four-footed animal can be similarly simulated. .

In the case of reversing straight, if the reverse current is applied to the left and right motors 21L and 21R in the same manner as in FIG. In this way, the zigzag crawls backwards.

Next, the operation of minimizing the radius of rotation in the present invention will be described with reference to FIGS.

In the case where the traveling device 23 intends to rapidly change the driving direction to the left side, as shown in FIG. 6C, when a short period pulse is applied to the left motor 21L and a long period pulse is applied to the right motor 21R, In accordance with the short left pulse, the left front wheel 20L moves forward less right (FIG. 4), and in accordance with the long right pulse, the right front wheel 20R moves largely forward left (FIG. 5), resulting in a sharp left gear. You will change your driving direction.

At this time, in Figure 5 it can be seen that the front wheel (20L) and rear wheel (27L) is forcibly gathered by the link 34, it is possible to smoothly rotate rapidly. Therefore, it is possible to rotate in the minimum radius in a zigzag crawl.

Next, in the case of a small toy or a small robot, it may be necessary to repeatedly move the crawling device 23 back and forth (an in-situ step movement). In this case, if the left and right pulses are applied as shown in FIG. The step will be performed.

On the other hand, in order to adjust the speed, the pulse application period may be adjusted as shown in Fig. 6E (advanced speed adjustment). In order to increase the operation, the period in which the applied pulse is turned on is increased as shown in Fig. 6F (advanced operation).

In all of the above cases, a method of shorting both terminals of the coils of the motor should be taken so that the motor of the side to which the control pulse is not applied is in a non-returned holding state.

Although the preferred embodiment of the present invention has been described above, the present invention is not limited to this embodiment, but various modifications and changes can be made without departing from the spirit of the present invention.

For example, in FIG. 3, two rear wheels are shown. However, as shown in FIG. 7, the rear wheels are combined into one and a link structure can be installed so that the support structure of the rear wheel shaft can be rotated by a hinge coupled to the base plate. .

In addition, the link structure is used in the above, but the same function as the link structure, so that each of the gears at the position of the hinge 31 and the hinge 32, respectively, to use a belt with a gear groove inside, or to the front wheel shaft ( 24) and the rear wheel shaft (28) has a T-shaped structure facing each other and has a gear groove in the T-shaped portion facing each other so that the front wheel shaft 24 and the rear wheel shaft (28) is engaged with each other by the gear grooves. It is also possible.

On the other hand, the present invention disclosed in Fig. 3 or 7, the rear wheel shaft and the rear wheel in the same manner as the present invention in the rear wheel side in Figure 1 of the prior art, the arm 10 (Fig. 3, 7 in the front wheel shaft 24) Applicable) and this rear wheel shaft can also be applied to a link structure in the same manner as the present invention.

In addition, the above description has been given of the front wheel driving method in which the drive motor is installed on the front wheel, but the rear wheel driving method in which the driving motor is installed in the rear wheel operates in the same manner.

In addition, since the driving route is uneven, even if a straight pulse having the same pulse interval is applied in the crawling driving apparatus of FIG. 3, the front wheel 24 is actually inclined to the left and right sides due to the unevenness of the traveling route. The angles are different. In order to prevent such a case, an encoder for measuring the tilt angle (rotation angle) is installed at the hinge 26 so that the controller receives the output of the encoder and forms an inclination angle corresponding to the applied pulse interval. Accurate control is achieved.

By using the present invention as described above, it is possible to minimize the radius of rotation of the crawling traveling device to be able to smoothly travel along the travel path even if the path is sharply bent during driving.

Claims (7)

In a crawler, A flat plate-shaped base plate; A front wheel shaft rotatably installed by the first hinge on the base plate and provided with a front wheel; A rear wheel shaft rotatably installed by a second hinge on the base plate and having a rear wheel installed thereon;  A driving device for driving left and right wheels of the front wheel or the rear wheel;  A coupling member coupled to the front wheel shaft and the rear wheel shaft to collect the front wheel and the rear wheel in a direction to rotate; And a control device for alternately applying a control pulse signal to the drive device. The crawler driving device according to claim 1, wherein the coupling member has a link structure. According to claim 1, The coupling member is a crawl running device, characterized in that the structure for fastening the belt. According to claim 1, wherein the coupling member has a T-shaped structure in which the front wheel shaft and the rear wheel shaft facing each other and has a gear groove in the T-shaped portion facing each other, wherein the front wheel shaft and the rear wheel shaft to the gear grooves A crawler traveling device, characterized in that the structure is engaged with each other by. The crawler driving device according to claim 1, wherein the driving device uses a motor as a power source. The crawler driving device according to claim 1, wherein the driving device uses suction and repulsive force of the permanent magnet and the electromagnet as power. 2. The crawler driving apparatus according to claim 1, wherein an encoder for measuring a rotation angle is installed at the first hinge or the second hinge on the side where the driving device is installed, and the controller receives the output of the encoder. .

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