KR20180044524A - Remote control device - Google Patents

Abstract

The present invention provides a remote control device including: a support frame; three or more linear guides coupled to the support frame, and respectively including a guide device and a linear motion unit coupled to the guide device; a translational motion unit located in an inner space surrounded by the three or more linear guides; three or more parallel links for respectively connecting the translational motion unit to the linear motion unit, such that the translational motion unit and the linear motion unit are coupled to each other with a second degree of freedom; a position detection device for calculating a position of the translational motion unit; and a control unit coupled to the translational motion unit. According to the present invention, the control unit moves in the inner space surrounded by the linear guides or link arms, so that a space required for use and installation of the remote control device is minimized. In addition, a load applied to an actuator is reduced by compensating a load of a link mechanism constituting a control device by using a spring or the like, so that a reaction force generated by the actuator is increased.

Description

Remote control device

The present invention relates to a remote control device, and more particularly, to a remote control device that minimizes a space required for operation of a control device by applying a parallel mechanism.

Generally, a remote control device is a device for controlling the operation of a controlled device such as a robot, industrial equipment, medical equipment, and a training simulator by generating information such as a direction, a moving distance, and a force to be operated by a user.

In recent years, a haptic manipulation device that feeds various senses to a user by simulating linear motions and rotational motions using information about the magnitude and direction of force transmitted from the manipulated device is often used for more precise control.

However, the conventional remote control apparatus occupies a large space for performing a steering operation even if the mechanism itself is large or the size of the mechanism is small, and thus interference with peripheral apparatuses occurs and it is often difficult to use the remote control apparatus. Therefore, there is a problem in that it is necessary to reduce the function in the actual field or prepare a separate space for the control.

For example, Patent Document 1 discloses a steering apparatus in the form of a delta type parallel mechanism having three link arms.

However, in the steering apparatus according to Patent Document 1, an input unit (a handle) is provided at a portion where three link arms protrude outward. Due to the characteristics of the mechanism, the input unit passes through a singular point located on the same plane, Since it is impossible to move, there is a limitation in reducing the space required for the steering operation. In addition, since the overall size varies depending on the operation of the input unit, there is a problem that sufficient control space must be secured in advance in order to avoid interference with the surroundings.

Registered Patent No. 10-0951817 (Announced on April 4, 2010)

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to minimize the space required for installation and use of the steering apparatus by using a parallel mechanism to perform a steering operation from the inside of the apparatus.

To achieve this object, one aspect of the present invention provides a support frame comprising: a support frame; At least three linear guides coupled to the support frame and each comprising a guide means and a straight moving portion coupled to the guide means; A translating moving portion located in an inner space surrounded by the three or more linear guides; Three or more parallel links connecting the translating moving part and the linear moving part, respectively, wherein the translating moving part and the linear moving part are coupled to each other with two degrees of freedom; Position detecting means for calculating a position of the translation portion; The remote control device including a control portion coupled to the translation portion.

In the remote control apparatus according to one aspect of the present invention, the linear guide includes a guide frame for supporting the guide means, and a first guide member provided at one end and the other end of the guide means, The position detecting means may include a rotation angle sensor provided on at least one of the first pulley and the second pulley. The first pulley or the second pulley may be coupled with an actuator for moving the straight line portion to provide a reaction force.

In the remote control apparatus according to one aspect of the present invention, the straight moving part is coupled to the nut of the ball screw, and at the end of the ball screw, at least one of the actuators for moving the straight moving part for providing reaction force with the rotation angle sensor One can be combined.

In the remote control apparatus according to one aspect of the present invention, the straight moving part is coupled to the distal end of the parallel link, the translating moving part is coupled to the rear end of the parallel link, Lt; / RTI >

In the remote control apparatus according to one aspect of the present invention, the straight moving part is coupled to the rear end of the parallel link and the translating moving part is coupled to the front end of the parallel link, . ≪ / RTI >

In a remote control apparatus according to an aspect of the present invention, at least one of a rotation connecting portion connecting the parallel link and the translating moving portion and a rotating connecting portion connecting the parallel link and the linear moving portion is provided with a load compensating spring .

[0011] Another aspect of the present invention provides a support frame comprising: a support frame; A first link coupled to the support frame and having one end coupled to the support frame at one freedom and extending forwardly of the support frame; a second link coupled to the other end of the first link at two degrees of freedom, At least three link arms each including a second link extending toward the first link; A translating portion located in an inner space surrounded by the three or more link arms and coupled to the inner end of the second link in two degrees of freedom; Position detecting means for calculating a position of the translation portion; The remote control device including a control portion coupled to the translation portion.

In the remote control apparatus according to the present invention, a rotary motion mechanism that rotates about at least one of a roll axis, a pitch axis, and a yaw axis may be coupled to the translation unit, and the control unit may be coupled to the rotary motion mechanism.

The rotation mechanism includes a roll shaft having one end rotatably coupled to the translating portion and the other end coupled to the control portion through a universal joint, a rotation angle sensor for detecting an amount of rotation of the roll shaft, A roll axis rotating mechanism including an actuator for rotating the roll axis to provide a reaction force; A yaw axis coinciding with a center of the universal joint; a first curved guide which rotates around the yaw axis and in which a slot through which the control section passes is formed in the longitudinal direction; A yaw axis rotating mechanism including a sensor and an actuator for rotating the yaw axis to provide a reaction force; A second curve guide having a pitch axis coinciding with a center of the universal joint, a second curve guide rotating about the pitch axis and having a slot through which the manipulator passes, and a rotation angle detecting unit for detecting a rotation amount of the pitch axis A pitch axis rotating mechanism including a sensor and an actuator for rotating the pitch axis for providing a reaction force. At this time, a handle is coupled to the periphery of the control unit, and an input unit for user operation is coupled to the handle.

The rotation mechanism includes a roll shaft pulley having one end fixed to the translating portion, a support frame rotatably coupled to the other end of the roll shaft pulley, and a rotation detecting unit coupled to the support frame, A roll axis rotating mechanism including an angle sensor and an actuator coupled to the support frame for rotating the roll shaft pulley to provide a reaction force; A C-type pitch axis pulley rotatably coupled to the support frame around a pitch axis, a rotation angle sensor coupled to the support frame for detecting a rotation amount of the C-type pitch axis pulley, And a pitch axis rotating mechanism including an actuator for rotating the C-type pitch axis pulley in order to supply the C type pitch axis pulley to the C type pitch axis pulley through a yaw axis.

The rotary motion mechanism may further include: a roll shaft rotating portion including a first member rotatably coupled to the translation portion through a roll shaft, and a second member extending in a direction perpendicular to the pitch axis in the first member; A pitch axis rotating part including a third member rotatably coupled to the second member through a pitch axis and a fourth member extending in a direction perpendicular to the yaw axis in the third member, And may be rotatably coupled to the fourth member.

According to the present invention, the space required for use and installation of the remote control apparatus can be minimized since the control section moves in the inner space surrounded by the plurality of straight guides or link arms. Also, by using a spring or the like, the load applied to the actuator can be reduced by compensating the load of the link mechanism constituting the steering apparatus, thereby increasing the reaction force by the actuator.

1 is a perspective view of a remote control apparatus according to a first embodiment of the present invention;
2 is a view showing a translational motion mechanism;
3 is a view showing a rotating mechanism;
4 is a view showing a straight guide
5 is a view showing a rotation connecting portion connecting a straight line moving portion and a parallel link;
Fig. 6 is a conceptual view showing the action of the load-
Figures 7A-7D show various operations of the translational motion mechanism
8 is a view showing a roll axis rotating mechanism of a rotating mechanism;
9 is a view showing a yaw axis rotating mechanism of a rotating mechanism;
10 is a view showing a pitch axis rotating mechanism of a rotating mechanism;
11 is a view showing a state in which a roll axis, a yaw axis, and a pitch axis rotating mechanism are combined;
12 is a view showing a coupling structure of the handle;
13 is a view showing a second embodiment of the rotating mechanism;
14 is a view illustrating the operation of the rotating mechanism according to the second embodiment;
15 is a view showing a roll axis rotating mechanism and a pitch axis rotating mechanism in the rotating mechanism according to the second embodiment;
16 is a sectional view showing a pitch axis rotating mechanism in the rotating mechanism according to the second embodiment
17 is a cross-sectional view showing a yaw axis rotating mechanism in the rotating mechanism according to the second embodiment
18 is a view showing a rotating mechanism according to the third embodiment;
19 is a view showing a modified example of the rotating mechanism according to the third embodiment
20 is a conceptual diagram illustrating a modified example of the remote control apparatus according to the first embodiment of the present invention.
21 is a perspective view of the remote control apparatus according to the second embodiment of the present invention.
22 is a view showing various operations of the remote control apparatus according to the second embodiment of the present invention;

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

It is to be understood that when an element is connected or coupled to another element in this specification, the element may be directly or indirectly connected to or coupled to another element, . Also, when an element is directly connected or coupled with another element, it means that no other element is interposed in between. Also, it is to be understood that a part including or including an element does not exclude other elements, but may further include or be equipped with other elements, unless specifically stated otherwise. Further, it should be noted that the drawings attached hereto are only illustrative for easy understanding of the gist of the invention, and thus the scope of the present invention should not be limited thereby.

FIG. 1 shows a remote control apparatus 10 according to a first embodiment of the present invention. The remote control apparatus 10 according to the first embodiment includes a translational motion mechanism 100 and a rotary motion mechanism 200 And a control unit (not shown) for detecting positional information of the translation unit 120 and rotation information of the rotary motion mechanism 200 and transmitting the rotation information to the controlled device.

Figure 2 illustrates a translator 100 including translator 120 and Figure 3 illustrates a translational motion of translator 120 relative to a roll axis, a yaw axis, and / or a pitch pitch axis of the rotating mechanism 200. As shown in FIG.

The remote control apparatus 10 according to the first embodiment of the present invention is characterized in that the rotary motion mechanism 200 is located inside the translational motion mechanism 100. [

With this configuration, since the operation range of the translating movement unit 120 and the rotation movement mechanism 200 is limited to the inside of the translating motion mechanism 100, the external shape and size of the entire mechanism do not change even if the user operates the apparatus. Therefore, compared with the conventional remote control apparatus, the space required for use is greatly reduced, and there is no need to secure a space required for operation in advance.

The translational motion mechanism 100 is, as shown in Fig. First to third linear guides 110a, 110b and 110c protruding from one side of the support frame 102 and one side of the support frame 102, one end of each of the first to third linear guides 110a, 110b and 110c, 130b and 130c and the translating unit 120 connected to the other ends of the first to third parallel links 130a, 130b and 130c. A base 101 to be mounted on the floor may be coupled to the lower end of the support frame 102.

The first to third linear guides 110a, 110b, and 110c are equiangularly spaced relative to the center of the support frame 102 and are disposed in parallel with each other. However, the first to third linear guides 110a, 110b, and 110c may not be disposed at equal angles to each other, and may not be parallel to each other.

The first to third linear guides 110a, 110b and 110c each have a guide frame 111, a guide rail 112 supported by the guide frame 111, And a moving unit 113. Therefore, the straight line moving part 113 can reciprocate linearly along the guide rail 112. A guide shaft may be used instead of the guide rail 112.

Since the position of the translating portion 120 is determined according to the position of each straight line moving portion 113, the position of each straight line moving portion 113 can be confirmed on the first to third straight line guides 110a, 110b, and 110c It is preferable to provide the position detecting means.

Pulleys 115 and 116 are coupled to one end and the other end of the guide frame 111 and a belt or a wire (not shown in the figure) is inserted between the straight moving part 113 and the respective pulleys 115 and 116, And a rotation angle sensor (not shown in the figure) can be installed on at least one of the pulleys 115 and 116. [

In this way, the amount of rotation of each of the pulleys 115 and 116 can be known through the rotation angle sensor, and position information such as the moving distance and direction of the straight line moving part 113 can be confirmed. The position of the translating moving part 120 can be calculated by using the position information of the straight moving part 113 of each of the linear guides 110a, 110b, and 110c.

At this time, if the actuator 118 is attached to at least one of the pulleys 115 and 116, the straight moving part 113 can be moved, thereby providing various reaction forces that the user can feel.

As another example, each straight line moving part 113 is connected to a nut of a ball screw (not shown) installed in the guide frame 111, a rotation angle sensor is attached to the rotation axis of the ball screw, And calculate the position of the translating portion 120 using the calculated distance.

In the above description, the position of the straight line moving part 113 is detected by using the rotation angle sensor, but the position confirming part of the straight line moving part 113 is not limited thereto.

The ends of the first to third parallel links 130a, 130b and 130c are connected to the first to third linear guides 110a, 110b and 110c by the first to third rotation connecting portions 140a, 140b and 140c, respectively. Each straight line is coupled to the moving part 113.

5 illustrates a first rotation connection part 140a. The first rotation connection part 140a includes a connection block 141 that is coupled to the linear movement part 113, an axis coupling part A first rotating shaft 143 rotatably coupled to the shaft coupling portion 142 and a second rotating shaft 143 rotatably coupled to one end of the first parallel link 130a at both ends of the first rotating shaft 143, And includes a rotation shaft 145.

Accordingly, one end of the first parallel link 130a has two degrees of freedom with respect to the straight moving portion 113 of the first linear guide 110a. Similarly, one end of each of the second and third parallel links 130b and 130c has two degrees of freedom with respect to the straight moving portion 113 of the second and third linear guides 110b and 110c.

In order to prevent the first to third parallel links 130a, 130b and 130c from moving in the same plane, the first and second parallel links 130a, 130b, The first rotary shaft 143 connecting the first rotary shaft 143 and the second linear link 130b of the second linear guide 110b and the linear movement of the third linear guide 110c, 113 and the third parallel link 130c are not parallel to each other.

It is preferable that the coupling structure is applied to the other ends of the first to third parallel links 130a, 130b, and 130c to couple the translating portion 120 to the translating portion 120 with two degrees of freedom.

5, a load compensation spring 147 may be installed on the first rotation shaft 141 coupled to both ends of the first to third parallel links 130a, 130b, and 130c. When the load compensating spring 147 is installed, the load applied to the actuator 118 is reduced and the inertial load is minimized, so that the actuator 118 can provide a reaction force that the user can feel with less force.

The load compensation spring 147 may be provided at both ends of the first to third parallel links 130a, 130b, and 130c, or may be installed only at a portion thereof. In any case, as shown in Fig. 6, it is preferable that a load-compensating spring 147 is provided in a direction to raise the center load of the mechanism.

In the embodiment of the present invention, the torsion spring is used as the load compensation spring 147, but the present invention is not limited to this, and other types of springs may be used. In place of the load compensating spring 147, a counterbalance for mechanically compensating the load may also be provided.

In place of the load compensating spring 147, the actuator 118 may also generate a load in a direction opposite to the inertial load. However, this method has a disadvantage in that the load applied to the actuator 118 increases, and the bodily sensation force of the reaction force provided by the actuator 118 is reduced.

Figs. 7A to 7D show the operation of the translator 100. Fig. 7A, the straight line moving portion 113 of the third linear guide 110c advances in the direction away from the support frame 102, The straight moving portions 113 of the first and second linear guides 110a and 110b are moved backward in the direction in which they approach the supporting frame 102, respectively.

7B, the linear moving part 113 of the third linear guide 110c is moved backward and the first and second linear guides 110a and 110b are moved backward, And 110b, respectively.

7C, the straight moving portions 113 of the first and third linear guides 110a, 110c are advanced respectively, and the second straight line 110a, And the straight moving portion 113 of the guide 110b is moved backward.

7D, the straight moving portions 113 of the first and third linear guides 110a, 110c are moved backward, and the second straight line portions 110a, The straight moving portion 113 of the guide 110b advances.

Meanwhile, the rotating mechanism 200 according to the first embodiment of the present invention includes at least one of a roll shaft rotating mechanism, a yaw shaft rotating mechanism, and a pitch shaft rotating mechanism.

Since the rotary motion mechanism 200 is positioned inside the first to third linear guides 110a, 110b and 110c of the translational motion mechanism 100 as described above, Should be small and the load generated on the rotating shaft should be reduced. For this purpose, it is preferable that the roll axis, the yaw axis, and the pitch axis are configured to pass through one point.

8 shows a roll shaft rotating mechanism and includes a roll shaft 230, a roll shaft gear 231 coupled to the roll shaft 230, a driving gear 234 meshing with the roll shaft gear 231, a driving gear 234 A sensor gear 237 meshing with the roll shaft gear 232, and a rotation angle sensor 236 shaft-coupled to the sensor gear 237. [

The roll shaft 230 is a rotational center of the roll shaft rotating mechanism, the rear end of the roll shaft 230 is rotatably coupled to the translating moving part 120, and the bar shaped control part 210 is coupled to the leading end thereof.

It is preferable that the position of the actuator 233, the drive gear 234, the rotation angle sensor 236, the sensor gear 237 and the like is fixed with respect to the translating portion 120.

The control unit 210 is a portion to which a user's steering operation is input. In the embodiment of the present invention, the control unit 210 is coupled to the roll shaft 230 through the universal joint 220. However, the present invention is not limited to this, and the control unit 210 and the roll shaft 230 may be coupled using other multi-degree of freedom connection means such as a ball joint.

The actuator 233 is for providing haptic feedback to the control unit 210 and the rotation angle sensor 236 is for detecting rotation angle information of the roll shaft 230. [ The sensor gear 237 may be omitted and the rotation angle sensor 236 may be axially coupled to the drive gear 234 on the opposite side of the actuator 233. [

Accordingly, when the user rotates the control unit 210, the roll shaft 230 rotates, and the rotation angle of the roll shaft 230 can be detected using the rotation angle sensor 236. Further, when the driving gear 234 is rotated by the actuator 233, the user can sense the reaction force through the control unit 210.

9 shows a yaw axis rotating mechanism, which includes a first curved guide 251 having a predetermined width and having a slot 252 penetrating along the length thereof, and a first curved guide 251 having a predetermined width and being provided at both ends of the first curved guide 251 A yaw axis gear 254 coupled to the upper end of the first curved surface guide 251 through a yaw axis 250 and a yaw axis 250, a driving gear 255 meshing with the yaw axis gear 254, An axis-coupled actuator 256, and a rotation angle sensor 257 coupled to the lower end of the first curved guide 251 through the yaw axis 250.

The actuator 256 is for providing haptic feedback to the control unit 210 and the rotation angle sensor 257 is for detecting rotational angle information of the yaw axis 250.

The rotation angle sensor 257 may be coupled to the yaw axis 250 at the upper end of the first curved surface guide 251 or may be axially coupled to the drive gear 255 at the opposite side of the actuator 256.

It is preferable that the positions of the yaw axis gear 254, the actuator 256, the drive gear 255, the rotation angle sensor 257, and the like are fixed with respect to the translation movement portion 120.

The first curved guide 251 may be curved or spherical. The control part 210 is inserted into the slot 252 of the first curved guide 251 so that the universal joint 220 and the roll shaft 230 are positioned inside the first curved guide 251.

The center of rotation of the yaw axis 250 preferably coincides with the center of rotation of the universal joint 220.

The slot 252 is formed in a direction from the upper end to the lower end of the first curved surface guide 251 so that when the control unit 210 passing through the slot 252 is moved in the vertical direction, When the control unit 210 is moved in the left-right direction, the control unit 210 applies a force to the first curved surface guide 251 in the left-right direction. Therefore, the rotational movement about the yaw axis 250 .

A cylindrical bearing 240 may be coupled to the portion of the controller 210 inserted in the slot 252 for reducing friction.

10 shows a pitch axis rotating mechanism, which includes a second curved guide 271 having a predetermined width and having a slot 272 penetrating along the length thereof, and a second curved guide 271 having a slot 272 formed at both ends of the second curved guide 271 A pitch axis gear 274 coupled to one end of the second curved surface guide 271 through a pitch axis 270, a driving gear 275 meshing with the pitch axis gear 274, And a rotation angle sensor 277 coupled to the other end of the second curved surface guide 271 through the pitch axis 270. The actuator 276 is rotatably coupled to the first curved surface guide 275 through a shaft 271,

The actuator 276 is for providing haptic feedback to the control unit 210 and the rotation angle sensor 277 is for detecting rotational angle information of the pitch axis 270. [

The rotation angle sensor 277 may be coupled to the pitch axis 270 at the other end of the second curved surface guide 271 or may be axially coupled to the drive gear 275 at the opposite side of the actuator 276.

It is preferable that the position of the pitch axis gear 274, the actuator 276, the drive gear 275, the rotation angle sensor 277 and the like is fixed with respect to the translating movement portion 120.

The second curved guide 271 may be curved or spherical. The control unit 210 is inserted into the slot 272 of the second curved guide 271 so that the universal joint 220 and the roll shaft 230 are located inside the second curved guide 251.

The center of rotation of the pitch axis 230 preferably coincides with the center of the universal joint 220.

The slot 272 is formed in a direction from one end of the second curved surface guide 271 to the other end so that when the control unit 210 passing through the slot 272 is moved in the left and right direction, When the control unit 210 is moved in the vertical direction, the control unit 210 applies a force to the second curved surface guide 271 in the vertical direction. Therefore, A rotational motion is generated.

11 shows a state in which both the above-described roll axis rotating mechanism, yaw axis rotating mechanism, and pitch axis rotating mechanism are assembled, and the second curved surface guide 271 of the pitch axis rotating mechanism, Is disposed on the outer side of the first curved surface guide 251 of the yaw axis rotating mechanism. However, the present invention is not limited thereto, and the second curved guide 271 may be located inside the first curved guide 251.

In this state, the user can grasp the control unit 210 to roll, urge, and / or pitch rotate the translating mechanism 200 or to move the translating unit 120 in a desired direction.

Further, in order to facilitate the user's operation, a handle 290 having a proper diameter may be further coupled to the control unit 210 as shown in FIG. At this time, the knob 290 must be fixed to the control unit 210 in order to prevent the knob 290 from idling.

In addition, an input unit 282 such as a button or a switch for inputting an additional command can be installed around the knob 290. In this case, it is preferable that the input unit 282 maintains a predetermined position even if the handle 290 rotates. To this end, as shown in FIG. 12, a cylindrical connecting unit 280 which does not rotate to the rear end of the handle 290 is engaged .

The connecting portion 280 is formed with a coupling groove 285 through which a second curved guide 271 is inserted at a rear end thereof and is installed to be movable along the second curved guide 271. The handle 290 and the control unit 210 are installed so as to pass through the inside of the connection unit 280.

Therefore, even if the user rotates the handle 290, the connecting portion 280 is caught by the second curved surface guide 271 and does not rotate. When the input unit 282 is provided in the connection unit 282, the position of the input unit 282 is maintained even if the user rotates the knob 290.

In the first embodiment of the present invention, the handle 290 has a bar shape, and the handle 290 having such a shape is advantageous in that the user can grasp the handle 290 with the fingertip and control it with precision. Further, if the handle 290 is rolled up with the palm of the hand, the input unit 282 can be operated by using the thumb or the index finger.

Meanwhile, the rotary motion mechanism 200 used in the remote control apparatus 10 is not limited to the above-described embodiments, and may be modified into various forms. Hereinafter, this will be described.

13 shows a rotating mechanism 300 according to the second embodiment. The rotating mechanism 300 according to the second embodiment also includes a roll shaft rotating mechanism, a yaw shaft rotating mechanism, a pitch pitch axis rotation mechanism, and thus can perform roll, yaw, and / or pitch motion as shown in Fig.

15 is a view illustrating a state in which a roll axis rotating mechanism and a pitch axis rotating mechanism are combined in the rotating mechanism 300 according to the second embodiment.

The roll shaft rotating mechanism includes a roll shaft pulley 340 having a distal end fixed to the translating moving part 120, a support frame 390 rotatably coupled to the roll shaft pulley 340, a control part 310 coupled to the support frame 390, ).

A driving pulley 342 axially coupled to the actuator 344 and the actuator 344 is provided on one side of the support frame 390 and a sensor pulley 346 and a sensor pulley 346 are provided on the other side of the support frame 390 An axis-coupled rotation angle sensor 348 is installed. At this time, the sensor pulley 346 may be omitted and the rotation angle sensor 348 may be provided on the opposite side of the actuator 344 from the drive pulley 342.

Although not shown in the drawings, the roll shaft pulley 340 and the drive pulley 342 are connected by a wire, and the roll shaft pulley 340 and the sensor pulley 346 are also connected by a wire.

Therefore, when the user holds the control unit 310 and rotates about the roll axis, the support frame 390 rotates about the roll shaft pulley 340 in a state where the roll shaft pulley 340 is fixed to the translating movement unit 120, . Since the sensor pulley 346 rotates in this process, the rotation angle of the roll shaft pulley 340 can be detected using the rotation angle sensor 348.

When the actuator 344 rotates the drive pulley 340 in a predetermined direction, the roll shaft pulley 340 connected to the drive pulley 342 rotates, and the user can sense the reaction force through the control unit 310.

The pitch axis rotating mechanism includes a C type pitch axis pulley 320 and a plurality of rollers 329 mounted on the support frame 390 for movably supporting the periphery of the pitch axis pulley 320, An actuator 324 coupled to one side of the drive pulley 322 and a rotation angle sensor 326 coupled to the other side of the drive pulley 324. The rotation angle sensor 326 and the actuator 324 may be separately disposed in consideration of interference with the translational motion mechanism without coupling the actuator 324 to the drive pulley 322. [

A plurality of rollers 329 are installed along the rotational locus of the pitch axis pulley 320 as shown in FIG.

The center of curvature of the C-type pitch-axis pulley 320 is the pitch axis. The C-type pitch-axis pulley 320 is disposed between the upper and lower ends of the pitch-axis pulley 320 via the yaw axis 360, The D-shaped knob 310 can be realized by mounting the part 310 to the user's hand. D-type handle is a type that can be a strong grip.

The pitch axis pulley 320 and the drive pulley 324 are connected by a wire. For example, after one end of the wire fixed to the pitch axis pulley 320 is wound on the drive pulley 324 one or more times, And can be fixed to the shaft pulley 320.

In this state, when the user holds the control unit 310 and rotates about the pitch axis, the pitch axis pulley 320 rotates along the roller 329. Since the driving pulley 322 rotates in this process, the rotation angle of the pitch axis pulley 320 can be detected by using the rotation angle sensor 326.

When the actuator 324 rotates the drive pulley 320 in a predetermined direction, the pitch axis pulley 320 connected to the drive pulley 322 rotates, and the user can feel the reaction force through the control unit 310 .

As shown in Fig. 17A, the yaw axis rotating mechanism includes a yaw axis 360 coupled to the lower end of the C-type pitch axis pulley 320, a yaw axis pulley 362 coupled to the yaw axis 360, A drive pulley 364 disposed at one side of the yaw shaft pulley 362, an actuator 366 axially coupled to the drive pulley 364, and a rotation angle sensor 368 axially coupled to the yaw shaft pulley 362.

The yaw axis rotating mechanism in the rotational exercise device 300 according to the second embodiment rotates about the yaw axis 360 with respect to the pitch axis pulley 320. [

The yaw axis pulley 362 and the drive pulley 364 are connected by a wire. The wire connecting the yaw axis pulley 362 and the drive pulley 364 is rotated around the yaw axis pulley 362 with one end fixed to the pitch axis pulley 320 to wind the drive pulley 364 more than once, 362 and the other end is fixed to the pitch axis pulley 320.

The rotation angle sensor 368 can detect the rotation angle of the pitch axis pulley 320 when the user rotates the control unit 320 about the yaw axis 360 and can detect the rotation angle with respect to the pitch axis pulley 320 using the actuator 366 It is possible to generate a rotational reaction force around the yaw axis 360.

17 (b) shows a modified example of the yaw axis rotation mechanism. The yaw axis pulley 362 fixed to the lower end of the C-type pitch axis pulley 320, the drive pulley 364 disposed on one side of the yaw axis pulley 362, An actuator 366 axially coupled to one side of the drive pulley 364, and a rotation angle sensor 368 axially coupled to the other side of the drive pulley 364.

When the yaw axis pulley 362 is fixed to the pitch axis pulley 320, the drive pulley 364 is wound at least once in a state where one end of the wire is fixed to the yaw axis pulley 362, and the other end is wound on the yaw axis pulley 362 And fix it.

When the user holds the control unit 310 and rotates about the yaw axis, the drive pulley 364 rotates, so that the rotation angle can be detected through the rotation angle sensor 368. When the actuator 366 is driven by the drive pulley 364 Is rotated in a predetermined direction, the control unit 310 rotates so that the user can feel the reaction force.

At least a part of the yaw axis 360, the yaw axis pulley 362, the drive pulley 364, the actuator 366 and the rotation angle sensor 368 shown in Figs. 17 (a) and 17 (b) As shown in FIG. At this time, an input unit such as a button or a switch may be provided in the control unit 310 for the additional function, or a means for giving additional degree of freedom may be provided in the control unit 310. [

In the rotating mechanism 200 according to the second embodiment described above, it is preferable that both of the rotational center line of the roll shaft pulley 340 and the center line of the yaw axis 360 pass through the rotation center of the pitch axis pulley 340 .

FIG. 18 shows a rotating mechanism 400 according to the third embodiment, and has a three-degree-of-freedom configuration that rotates about a roll axis, a pitch axis, and a yaw axis as in the above-described embodiment.

Specifically, the rotating mechanism 400 according to the third embodiment includes a roll shaft rotating part 420 coupled to the translating moving part 120 so as to be rotatable about a roll axis, And a control unit 410 rotatably coupled to the pitch axis rotation unit 430 about a yaw axis.

The roll shaft rotation unit 420 includes a first member 421 rotatably coupled to the translation unit 120 through a roll axis and a second member 421 bent at one end of the first member 421 and extending in a direction perpendicular to the pitch axis. Member 422 as shown in FIG.

The pitch axis rotating part 430 includes a third member 431 rotatably coupled to the second member 422 of the roll axis rotating part 420 via a pitch axis, a third member 431 bent in one end of the third member 431, And a fourth member 432 extending from the first member 432 to the second member 432.

The control member 410 is coupled to the fourth member 432 through a yaw axis.

The rotation center of the roll axis rotation unit 420, the rotation center of the pitch axis rotation unit 430, and the rotation center of the control unit 410 in the rotation mechanism 400 according to the third embodiment are configured to pass through one point desirable.

Also, although not shown in the drawing, a rotation angle sensor, an actuator, and the like may be directly attached to each rotary shaft or may be indirectly coupled through a wire, a belt, a gear, a chain, or the like as in the above embodiment.

The rotary motion mechanism 400a shown in FIG. 19 is a modification of the rotary motion mechanism 400 according to the third embodiment, and is different from FIG. 18 in that a hand-operated control portion 410a is mounted.

In the remote control apparatus 100 according to the first embodiment of the present invention, as shown in the conceptual diagram of FIG. 6, the rear end (the end portion on the support frame side) of the first to third parallel links 130a, 130b, And the translating portion 120 is positioned inside the parallel links 130a, 130b, and 130c.

However, as shown in the conceptual diagram of Fig. 20, the configuration may be reversed. That is, the distal ends of the first to third parallel links 130a, 130b, and 130c are connected to the translating portion 120, and the respective rear ends are connected to the straight lines of the first to third straight guides 110a, 110b, And may be coupled to the moving unit 113. Since the translation portion 120 is located on the outer side of the parallel links 130a, 130b, and 130c, the steering distance in the forward and backward directions is long. However, the first to third straight guides 110a, 110b, and 110c Since it is possible to control from the inside, there is an advantage that the control space can be reduced.

Hereinafter, a remote control device 30 according to a second embodiment of the present invention will be described with reference to FIG.

The remote control apparatus 30 according to the second embodiment includes the translational motion mechanism 500 and the rotation motion mechanism 400 and the translational motion mechanism 500 includes the support frame 502 and the translating movement unit 520 510a, 510b, and 510c, and the rotational motion mechanism 400 is coupled to the translating portion 520. The first link arm 510a, the second link arm 510b,

A base 501 to be mounted on the floor may be coupled to the lower end of the support frame 502.

The first to third link arms 510a, 510b and 510c of the translational motion mechanism 500 include a first link 511 and a second link 512, respectively. One end of each first link 511 is rotatably coupled to the support frame 502 and the other end is rotatably connected to one end of the second link 512. The other end of each second link 512 is rotated And is rotatable to the east portion 520. Particularly, one end and the other end of the second link 512 are coupled to the first link 511 and the translating portion 520 by the rotation connecting portion 513 having two degrees of freedom.

A load compensating spring may be installed at the rotary connection portion provided at the end of the first link 511 or the second link 512 in the first through third link arms 510a, 510b, and 510c. In addition, a rotation angle sensor for measuring the rotation angle and / or an actuator for generating reaction force may be installed on the rotation shaft of each rotation connection part.

Meanwhile, in the remote control apparatus 30 according to the second embodiment of the present invention, the translating unit 520 is preferably positioned inside the first through third link arms 510a, 510b, and 510c. This is because the use space can be reduced compared with the conventional steering apparatus.

To this end, the first links 511 of the first to third link arms 510a, 510b and 510c extend toward the front of the support frame 502, respectively, and the second links 512 extend from the first links 511 In the direction toward the support frame 502.

Therefore, when the translating portion 520 is connected to the inner end of each second link 512, the translating portion 520 is positioned in the inner space surrounded by the first to third link arms 510a, 510b and 510c .

The remote control apparatus 30 according to the second embodiment can also be provided with position detection means for estimating the position of the translating portion 520. [ The position detecting means may be a rotation angle sensor provided on the rotation link provided at the end of the first link 511 or the second link 512. [

Since the rotary motion mechanism 400 is the same as that described with reference to Fig. 18, a description thereof will be omitted. Needless to say, such a rotating mechanism 400 can be replaced with other types of rotating mechanisms 200, 300, 400a described above.

22 is a diagram showing various operations of the remote control apparatus 30 according to the second embodiment.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

For example, in the above-described embodiment, the translating exercising apparatuses 100 and 500 and the rotating exercising apparatuses 200 and 300 are included in the remote control apparatuses 10 and 30, but the present invention is not limited thereto. ).

As another example, the translator 100, 500 described above includes three parallel links 130a, 130b, 130c or three link arms 510a, 510b, 510c, but is not limited thereto. More than two parallel links or link arms.

As another example, all of the rotating mechanisms 200, 300, and 400 described above include a three-axis rotating mechanism. But it is not limited thereto and may include only a single-axis or two-axis rotation mechanism or may include more rotation shafts.

Also, in the embodiment of the present invention, gears, pulleys, wires, and the like are used for transmission of power or rotational force. However, the power transmission means or the rotational force transmission means is not limited to this and other types such as belt, .

In addition, the installation posture of the translator 100, 500 is not limited to that shown in the drawings, and the installation direction and the installation angle may be variously changed depending on the installation environment, the intention of the user, the operation range,

It is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

10, 30: remote control device 100: translational motion device 101: base
102: support frame 110a, 110b, 110c: first, second, third straight guide
111: guide frame 112: guide rail 113:
115, 116: pulley 118: actuator 120: translational motion
130a, 130b, 130c: first, second, and third parallel links
140a, 140b, 140c: first, second,
141: connection block 142: shaft coupling portion 143: first rotation shaft
145: second rotating shaft 147: load compensating spring 200: rotating body
210: steering part 220: universal joint 230: roll axis
231: Roll-axis gear 233: Actuator 234: Drive gear
236: rotation angle sensor 237: sensor gear 240: cylindrical bearing
250: yaw axis 251: first curved guide 252: slot
254: Yaw axis gear 255: Drive gear 256: Actuator
257: rotation angle sensor 270: pitch shaft 271: second curved surface guide
272: Slot 274: Pitch axis gear 275: Drive gear
276: actuator 277: rotation angle sensor 280:
282: Input part 285: Coupling groove 290: Handle
300: Rotating mechanism 310: Maneuvering unit 320: Pitch axis pulley
322: drive pulley 324: actuator 326: rotation angle sensor
329: roller 340: roll shaft pulley 342: drive pulley
344: actuator 346: sensor pulley 348: rotation angle sensor
360: yaw axis 362: yaw axis pulley 364: drive pulley
366: actuator 368: rotation angle sensor 390: support frame
400: Rotating mechanism 410: Maneuvering part 420: Roll axis rotating part
421: first member 422: second member 430: pitch-
431: third member 432: fourth member 500: remote control device
501: base 502: support frame 510a, 510b, 510c: first, second and third link arms
511: first link 512: second link 513:
520: Translation is in the east

Claims (16)

A support frame;
At least three linear guides coupled to the support frame and each comprising a guide means and a straight moving portion coupled to the guide means;
A translating moving portion located in an inner space surrounded by the three or more linear guides;
Three or more parallel links connecting the translating moving part and the linear moving part, respectively, wherein the translating moving part and the linear moving part are coupled to each other with two degrees of freedom;
Position detecting means for calculating a position of the translation portion;
The control unit coupled to the translation unit
≪ / RTI > The method according to claim 1,
Wherein the linear guide includes a guide frame for supporting the guide means and a first pulley and a second pulley respectively installed at one end and the other end of the guide means and connected to the linear portion through a wire,
Wherein the position detecting means includes a rotation angle sensor provided on at least one of the first pulley and the second pulley. 3. The method of claim 2,
Wherein the first pulley or the second pulley is coupled to an actuator for moving the straight moving part to provide a reaction force. The method according to claim 1,
Wherein at least one of the actuators for moving the linear moving part is coupled to an end of the ball screw for providing a reaction force with a rotation angle sensor. The method according to claim 1,
Wherein the straight moving part is coupled to the distal end of the parallel link and the translating moving part is coupled to the rear end of the parallel link and the translating moving part is located inside the parallel link. The method according to claim 1,
Wherein the straight moving part is coupled to the rear end of the parallel link and the translating moving part is coupled to the front end of the parallel link and the translating moving part is located outside the parallel link. The method according to claim 1,
Wherein a load compensation spring is installed on at least one of a rotation connection portion connecting the parallel link and the translation portion and a rotation connection portion connecting the parallel link and the linear movement portion. A support frame;
A first link coupled to the support frame and having one end coupled to the support frame at one freedom and extending forwardly of the support frame; a second link coupled to the other end of the first link at two degrees of freedom, At least three link arms each including a second link extending toward the first link;
A translating portion located in an inner space surrounded by the three or more link arms and coupled to the inner end of the second link in two degrees of freedom;
Position detecting means for calculating a position of the translation portion;
The control unit coupled to the translation unit
≪ / RTI > The method according to claim 1 or 8,
Wherein a rotary motion mechanism for rotating the rotary shaft about at least one of a roll axis, a pitch axis and a yaw axis is coupled to the translation unit, and the control unit is coupled to the rotary motion mechanism. 10. The apparatus according to claim 9,
A roll shaft whose one end is rotatably coupled to the translation portion and the other end is coupled to the control portion through a universal joint, a rotation angle sensor for detecting a rotation amount of the roll shaft, A roll axis rotating mechanism including an actuator for rotating the shaft;
A yaw axis coinciding with a center of the universal joint; a first curved guide which rotates around the yaw axis and in which a slot through which the control section passes is formed in the longitudinal direction; A yaw axis rotating mechanism including a sensor and an actuator for rotating the yaw axis to provide a reaction force;
A second curve guide having a pitch axis coinciding with a center of the universal joint, a second curve guide rotating about the pitch axis and having a slot through which the manipulator passes, and a rotation angle detecting unit for detecting a rotation amount of the pitch axis A pitch axis rotating mechanism including a sensor and an actuator for rotating the pitch axis for providing a reaction force,
And a remote control device 11. The method of claim 10,
Wherein a handle is coupled to the periphery of the control unit and an input unit for user operation is coupled to the handle. 10. The apparatus according to claim 9,
A support shaft rotatably coupled to the other end of the roll shaft pulley; a rotation angle sensor coupled to the support frame and detecting a rotation amount of the roll shaft pulley; A roll axis rotating mechanism including an actuator for rotating the roll shaft pulley to provide a reaction force;
A C-type pitch axis pulley rotatably coupled to the support frame around a pitch axis, a rotation angle sensor coupled to the support frame for detecting a rotation amount of the C-type pitch axis pulley, Type pitch-axis pulley for providing a pitch-axis-pitch pulley, and an actuator for rotating the C-
Wherein the control unit is coupled to the C-type pitch axis pulley through a yaw axis. 10. The apparatus according to claim 9,
A roll shaft rotating part including a first member rotatably coupled to the translation part through a roll shaft and a second member extending in a direction perpendicular to the pitch axis in the first member;
A third member rotatably coupled to the second member through a pitch axis, and a fourth member extending in a direction perpendicular to the yaw axis in the third member;
Wherein the control unit is rotatably coupled to the fourth member via a yaw axis. 1. A rotary motion instrument for use in a remote control apparatus for generating a control command using translational motion and rotary motion,
A roll shaft whose one end is rotatably coupled to the translation part of the translation mechanism and the other end is coupled to the control part through a universal joint, a rotation angle sensor for detecting the amount of rotation of the roll shaft, A roll axis rotating mechanism including an actuator for rotating the roll axis;
A yaw axis coinciding with a center of the universal joint; a first curved guide which rotates around the yaw axis and in which a slot through which the control section passes is formed in the longitudinal direction; A yaw axis rotating mechanism including a sensor and an actuator for rotating the yaw axis to provide a reaction force;
A second curve guide having a pitch axis coinciding with a center of the universal joint, a second curve guide rotating about the pitch axis and having a slot through which the manipulator passes, and a rotation angle detecting unit for detecting a rotation amount of the pitch axis A pitch axis rotating mechanism including a sensor and an actuator for rotating the pitch axis for providing a reaction force,
A rotating mechanism 1. A rotary motion instrument for use in a remote control apparatus for generating a control command using translational motion and rotary motion,
A rotary shaft rotatably coupled to the other end of the roll shaft pulley; a rotation angle sensor coupled to the support frame and detecting a rotation amount of the roll shaft pulley; A roll axis rotation mechanism coupled to the support frame and including an actuator for rotating the roll shaft pulley to provide a reaction force;
A C-type pitch axis pulley rotatably coupled to the support frame around a pitch axis, a rotation angle sensor coupled to the support frame for detecting a rotation amount of the C-type pitch axis pulley, Type pitch-axis pulley for providing a pitch-axis-pitch pulley, and an actuator for rotating the C-
And a control section held by a user is rotatably coupled to the C-type pitch axis pulley through a yaw axis. 1. A rotary motion instrument for use in a remote control apparatus for generating a control command using translational motion and rotary motion,
A roll shaft rotating part including a first member rotatably coupled to the translation part of the translation mechanism through a roll axis and a second member extending in a direction perpendicular to the pitch axis in the first member;
A third member rotatably coupled to the second member through a pitch axis, and a fourth member extending in a direction perpendicular to the yaw axis in the third member;
Wherein the control unit is rotatably coupled to the fourth member via a yaw axis of the control unit gripped by a user,

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